Protective role of cellular prion protein against TNFα-mediated inflammation through TACE α-secretase

Although cellular prion protein PrPC is well known for its implication in Transmissible Spongiform Encephalopathies, its functions remain elusive. Combining in vitro and in vivo approaches, we here show that PrPC displays the intrinsic capacity to protect neuronal cells from a pro-inflammatory TNFα noxious insult. Mechanistically, PrPC coupling to the NADPH oxidase-TACE α-secretase signaling pathway promotes TACE-mediated cleavage of transmembrane TNFα receptors (TNFRs) and the release of soluble TNFR, which limits the sensitivity of recipient cells to TNFα. We further show that PrPC expression is necessary for TACE α-secretase to stay at the plasma membrane in an active state for TNFR shedding. Such PrPC control of TACE localization depends on PrPC modulation of β1 integrin signaling and downstream activation of ROCK-I and PDK1 kinases. Loss of PrPC provokes TACE internalization, which in turn cancels TACE-mediated cleavage of TNFR and renders PrPC-depleted neuronal cells as well as PrPC knockout mice highly vulnerable to pro-inflammatory TNFα insult. Our work provides the prime evidence that in an inflammatory context PrPC adjusts the response of neuronal cells targeted by TNFα through TACE α-secretase. Our data also support the view that abnormal TACE trafficking and activity in prion diseases originate from a-loss-of-PrPC cytoprotective function.


Results
PrP C coupling to the NADPH oxidase-TACE signaling pathway promotes TNFR1 shedding. Because the cell sensitivity to sTNFα depends on the amount of TNFRs present at the plasma membrane, we first sought to determine whether PrP C would impact on cell surface TNFR level focusing on TNFR type 1 (TNFR1), a transmembrane trimeric receptor composed of three identical subunits, that mainly relays sTNFα toxicity 14 .
Antibody mediated-PrP C ligation, used to mimic an activation signal for PrP C 5, 7 , elicited the release of soluble TNFR1 (sTNFR1) into the culture media of 1C11 neuroectodermal cells and their serotonergic 1C11 5-HT neuronal derivatives 15 as assessed by ELISA (Fig. 1a). sTNFR1 was detected as soon as 30 min after PrP C ligation with SAF61 antibody (10 µg ml −1 ). ELISA-based quantification of monomeric TNFR1 subunit in the culture medium revealed that the level of sTNFR1 reached at 120 min was ~4-fold above basal level (Fig. 1a). Concomitantly, immunofluorescence experiments that detect the trimeric form of TNFR1 at the plasma membrane showed that PrP C ligation triggered a time-dependent depletion of TNFR1 at the cell surface with a maximum immunostaining decrease (~1.5-fold) reached by 120 min exposure to SAF61 antibody (Fig. 1b,c). Inhibition of NADPH oxidase (diphenyleneiodonium-DPI, 100 µM) or TACE (TAPI-2, 100 µM) abrogated the shedding of TNFR1 induced by PrP C ligation ( Fig. 1a-c), indicating that PrP C coupling to the NADPH oxidase-TACE α-secretase signaling pathway controls cell surface TNFR1 level in 1C11 neuronal stem cells and their serotonergic progenies. Beyond the direct activation of TACE α-secretase by ROS through modification of the valence state of Zn 2+ at the catalytic site 16 , redox activation of guanylate cyclase (GC) and subsequent production of cGMP was also shown to promote TACE-dependent TNFR1 shedding in sepsis conditions 17 . We thus probed the involvement of GC in PrP C -induced TNFR1 shedding by inhibiting GC with NS-2028 (1 µM). We found that GC inhibition had no impact on sTNFR1 release induced by SAF61 antibody in 1C11 precursor cells ( Supplementary Fig. 1a), while TNFR1 shedding was 40% decreased in 1C11 5-HT cells ( Supplementary Fig. 1b). This result suggests that guanylate cyclase is a potential signaling intermediate in PrP C coupling to TACE α-secretase in 1C11 5-HT neuronal cells only.
ADAM10 and γ-secretase have also been involved in the shedding of TNFR1 18,19 . We thus probed the implication of these two proteases in the PrP C -regulated cleavage of TNFR1 using the pharmacological inhibitors GI254023X (50 nM) for ADAM10 and DAPT (10 µM) for γ-secretase. As assessed through the measure of sTNFR1 level in the cell culture medium, the inhibition of ADAM10 or γ-secretase had no effect on the release of TNFR1 ectodomain induced by PrP C ligation with SAF61 antibody in 1C11 and 1C11 5-HT cells ( Supplementary  Fig. 1a,b). This indicates that ADAM10 and γ-secretase play no role in PrP C -stimulated TNFR1 shedding.
Finally, we extended our study to other cell systems and found that PrP C -dependent control of TACE-mediated TNFR1 shedding also occurred in primary cultures of cerebellar granule neurons (CGNs). Exposure of CGNs to PrP antibodies (SAF61 10 µg ml −1 ) triggered a time-dependent decrease in the level of TNFR1 at the neuronal cell surface up to 240 min (Fig. 1d), which was cancelled by inhibiting TACE activity (Fig. 1d).
As a whole, these data indicate the amount of TNFR1 molecules expressed at the plasma membrane of neuronal stem cells and neurons depends on PrP C signaling that stimulates TNFR1 shedding via the NADPH oxidase-TACE α-secretase cascade.
PrP C -dependent regulation of TNFR1 shedding governs cell sensitivity to sTNFα toxicity. As PrP C intrinsically stimulates TACE-mediated TNFR1 shedding, we next assessed whether PrP C confers cell protection against sTNFα toxicity. To address such PrP C function, we exploited siRNA-mediated PrP C silenced cells and primary neurons from PrP 0/0 mice and compared the sensitivity to sTNFα of PrP C -depleted cells to that of their corresponding PrP C expressing counterparts. Time-course accumulation of sTNFR1 in the cell culture medium of 1C11 cells and 1C11 5-HT neuronal cells upon PrP C ligation with SAF61 PrP antibody (10 μg ml −1 ). TNFR1 shedding induced by PrP antibodies is abolished upon inhibition of NADPH oxidase with DPI (100 μM) or TACE with TAPI-2 (100 μM). *p < 0.01 vs. nontreated cells. **p < 0.01 vs. cells exposed to SAF61 antibody. (b-d) Immunofluorescence experiments and quantification histograms showing progressive TNFR1 depletion at the cell surface of 1C11 cells (b), 1C11 5-HT cells (c), and primary CGNs (d) exposed to SAF61 PrP antibody and cancellation upon addition of TAPI-2. Scale bar = 50 μm. # p < 0.05 vs. nontreated cells. *p < 0.05 vs. cells exposed to SAF61 antibody alone. Data shown are the mean ± SEM from three experiments performed in triplicate. We first determined the dose of exogenous sTNFα that induces 50% cell death (LD 50 TNFα ) of 1C11 precursor cells, serotonergic 1C11 5-HT neural cells and their counterparts silenced for PrP C expression (PrP null -cells). As shown in Fig. 2a and Table 1, PrP null -1C11 and 1C11 5-HT cells were ~5-to 9-fold more sensitive to a 48 h exposure to sTNFα than their corresponding PrP C expressing cells. In primary cultures of CGNs, we also found a PrP C role  Table 1. (c) Immunofluorescence experiments showing enhanced level of TNFR1 at the cell surface of PrP null -1C11 and PrP null -1C11 5-HT cells as well as PrP 0/0 CGNs as compared to their corresponding PrP C expressing cells (CTRL, WT). Scale bar = 50 µm. (d) ELISA-based quantification experiments indicating reduced concentration of sTNFR1 in the culture medium of PrP null -1C11/1C11 5-HT cells compared to PrP C expressing cells. *p < 0.01. (e) Western blots showing a stronger activation of caspase-3 in PrP null -1C11 5-HT cells exposed to sTNFα (10 ng ml −1 ) for 120 min than in PrP C expressing cells. Antagonizing either ROCK activity with Y-27632 (100 µM for 1 h) or PDK1 activity with BX912 (1 µM for 1 h) in PrP C -depleted cells reduces toxic action of sTNFα. # p < 0.05 vs. PrP C -expressing cells exposed to sTNFα. ## p < 0.05 vs. PrP null -cells treated with sTNFα. Data shown are the mean ± SEM from three experiments performed in triplicate.
in the control of cell sensitivity to sTNFα. In this set of experiments, we determined the dose of exogenous sTNFα inducing neuronal dysfunction for 50% of CGNs through dendrite fragmentation 13 . We monitored that CGNs isolated from PrP 0/0 -FVB mice were ~20-fold more sensitive to a 48 h exposure to sTNFα than PrP C -expressing CGNs ( Fig. 2b and Table 1).
Through immunofluorescence experiments, we recorded an increase of TNFR1 at the plasma membrane of PrP null -1C11 and 1C11 5-HT cells as well as PrP 0/0 -CGNs compared to their wild-type counterparts (Fig. 2c). Of note, the level of sTNFR1 in the cell culture medium of PrP null -1C11 and 1C11 5-HT cells was ∼10to 25-fold lower than that measured with wild type cells (Fig. 2d), indicating reduced shedding of cell surface TNFR1 in the absence of PrP C .
Corroborating the augmentation of plasma membrane TNFR1 level in PrP null -1C11/1C11 5-HT cells and PrP 0/0 -CGNs associated with the increased vulnerability of PrP C -depleted cells to sTNFα, we found that TNFR1 signaling is exacerbated in the absence of PrP C . In response to sTNFα exposure for 2 h, the activation of caspase-3, a downstream effector of TNFR1 signaling 20 , was ∼2 to 4-fold enhanced in PrP null -1C11 ( Supplementary Fig. 2) and PrP null -1C11 5-HT cells (Fig. 2e) compared to wild type cells.
Loss of PrP C therefore triggers a deficit of TNFR1 shedding, leading to plasma membrane accumulation of TNFR1 and enhanced TNFR1 death signaling, that renders PrP C -depleted cells highly vulnerable to sTNFα toxicity. Our data thus argue for a protective function of PrP C against sTNFα-associated inflammation.

Cancellation of TNFR1 shedding in PrP null -cells is associated with TACE internalization induced by ROCK-I and PDK1 kinases.
Defect in TNFR1 shedding caused by the absence of PrP C prompted us to examine the status of the TACE α-secretase in PrP null -cells. While no significant variation in TACE expression was measured at the mRNA and protein levels between PrP null -and PrP C -expressing cells (Fig. 3a), immunolabeling experiments revealed that TACE was quite absent at the plasma membrane of PrP null -cells but found intracellularly after cell permeabilization with saponin 0.05% (Fig. 3b). Transmission electron microscopy experiments further indicated that TACE was internalized in vesicles enriched with the caveolin-1 protein (Cav-1) in PrP null -1C11 cells (Fig. 3c). These observations suggest that loss of PrP C promotes TACE internalization.
Such internalization of TACE in PrP C -depleted cells is reminiscent of what we observed in prion-infected neurons 13,21 . We showed that pathogenic prions (PrP Sc ) overstimulate ROCK-I, which binds and phosphorylates PDK1, leading to PDK1 overactivity 21 . Overstimulated PDK1 promotes the phosphorylation and displacement of TACE from the plasma membrane to intracellular Cav-1-enriched vesicles in prion-infected neurons 13 . We thus probed whether the internalization of TACE and subsequent deficit in TNFR1 shedding in PrP null -cells would also relate to overactivation of the ROCK-I/PDK1 duo.
Immunoprecipitation experiments revealed that the pool of PDK1 molecules interacting with ROCK-I subtype was ~2-fold more abundant in PrP null -1C11 cells than in PrP C expressing cells (Fig. 3d). Such enhanced interaction between ROCK-I and PDK1 in PrP null -1C11 cells was accompanied by an increased PDK1 phosphorylation level (Fig. 3e), leading to a ~2-to 3-fold increase in PDK1 activity in PrP null -cells compared to their PrP C expressing counterparts (Fig. 3f).
In PrP null -cells, overactivation of the ROCK-I/PDK1 module compromises TACE localization at the plasma membrane. The inhibition of either ROCK-I with Y-27632 (100 µM) or PDK1 with BX912 (1 µM) for 1 h indeed allowed to direct TACE back to the plasma membrane of PrP null -cells (Fig. 3g). In addition, inhibition of ROCK-I or PDK1 in PrP null -cells rescued TACE cleavage activity towards TNFR1 as assessed by reduced level of TNFR1 at the plasma membrane ( Fig. 3g) and desensitization of PrP null -1C11 and 1C11 5-HT cells from sTNFα-induced caspase-3 activation ( Fig. 2e and Supplementary Fig. 2).
These results indicate that in the absence of PrP C overactivated ROCK-I and PDK1 kinases promote the internalization of TACE and neutralize TACE activity towards TNFR1. Beyond PrP C capacity to stimulate TACE-mediated TNFR1 shedding, the protective role of PrP C against sTNFα further depends on PrP C ability to maintain TACE α-secretase at the cell surface in an active state for TNFR1 cleavage.
The presence of active TACE α-secretase at the plasma membrane depends on PrP C -mediated regulation of β1 integrin signaling. In lipid rafts of the plasma membrane, PrP C is assumed to function as a dynamic platform for the assembly and modulation of the signaling activity of various modules 4 . Such PrP C role possibly relies on the interaction between PrP C and the membrane protein Cav-1 7, 22 that also mediates the recruitment of β1 integrins to rafts and activates β1 integrin signaling 23,24 . By controlling Cav-1 availability for β1 integrins 22 , PrP C exerts a negative regulatory action on β1 integrin signaling 6 . Such interplay between PrP C and β1 integrins in 1C11 neuronal stem cells and PC12 cells fine-tunes the ROCK activity necessary for  Table 1. Impact of PrP C depletion on cell sensitivity to sTNFα in 1C11 precursor cells, 1C11 5-HT neuronal cells and primary CGNs. LD 50 TNFα values correspond to the concentration of sTNFα inducing a 50% cell death in 1C11 and 1C11 5-HT cells or inducing dendritic fragmentation for 50% of neuronal cells in CGNs. Data are the mean ± SEM of three independent experiments performed in triplicate. neurite sprouting 6,25 . We next wondered whether loss of PrP C modulatory action on β1 integrin signaling would account for the ROCK-I/PDK1-dependent TACE internalization and subsequent defect in TNFR1 shedding in PrP null -cells.
Exposure of PrP null -1C11 cells to neutralizing antibodies towards β1 integrins (MAB1965) relocated TACE to the plasma membrane of PrP null -1C11 cells (Fig. 4a), arguing that β1 integrin overactivity in the absence of PrP C triggers TACE internalization. Redirection of TACE to the cell surface started after 60 min exposure to ΜΑΒ1965. Immunofluorescence experiments indicated that TACE signal measured at the plasma membrane of PrP null -1C11 cells after 120 and 240 min exposure to MAB1965 was comparable to that of PrP C expressing 1C11 cells. Correlating TACE relocation to the cell surface, neutralization of β1 integrins rescued TNFR1 shedding as assessed by the progressive disappearance of TNFR1 immunostaining at the plasma membrane of PrP null -1C11 cells exposed to MAB 1965 (Fig. 4a). After β1 integrin neutralization for 120 to 240 min, cell surface TNFR1 level in PrP null -cells was highly comparable to that measured with PrP C expressing cells. Manganese (Mn 2+ ) is widely used to investigate conformational changes associated with the activation of integrins and the recruitment of signaling pathways 26,27 , as Mn 2+ binds integrins and strongly up-regulates integrin function by mimicking inside-out signaling events 28,29 . In 1C11 and 1C11 5-HT cells expressing PrP C , forced stimulation of β1 integrin activity with 100 µM Mn 2+ for 4 h promoted the internalization of TACE (Supplementary Fig. 3a,c) and abrogated TACE-mediated shedding of TNFR1 ( Supplementary Fig. 3b,c) in a ROCK-I/PDK1-dependent manner. This set of experiments demonstrates that misregulation of β1 integrin signaling activity caused by loss of PrP C regulatory action over β1 integrins (in PrP null -cells or in Mn 2+ -treated PrP C expressing cells) is at the root of TACE internalization.
Finally, we monitored that restoration of TACE α-secretase at the plasma membrane and subsequent recovery of TNFR1 shedding in PrP null -cells exposed to the neutralizing β1 integrin antibody MAB1965 (240 min) were associated with disruption of the ROCK-I/PDK1 complex (Fig. 4b), reduced phosphorylation of PDK1 (Fig. 4c), decrease in PDK1 activity in PrP null -1C11 cells (Fig. 4d), and lower cell sensitivity to sTNFα, as inferred by the decreased sTNFα-induced activation of caspase-3 (Fig. 4e).
These overall data provide the prime evidence that loss of PrP C regulatory function towards β1 integrin signaling and downstream overactivation of ROCK-I trigger (i) PDK1 overactivation, (ii) PDK1-dependent TACE internalization and (iii) abrogation of TACE shedding activity. By modulating β1 integrin signaling and activation of the ROCK-I/PDK1 module, PrP C physiologically ensures bioavailability of active TACE α-secretase at the plasma membrane for TNFR1 shedding that thereby protects neuronal stem cells and neurons from sTNFα toxicity.
Enhanced sensitivity of PrP 0/0 mice to sTNFα inflammatory challenge can be counteracted upon PDK1 inhibition. To corroborate our in vitro data with the in vivo situation, we next probed in the brain of PrP 0/0 mice the status of PDK1, the TACE shedding activity towards TNFR1, and the sensitivity to sTNFα-mediated inflammation.
We next challenged FVB PrP 0/0 -mice and their PrP C expressing FVB counterparts (n = 6) with an icv dose of sTNFα (200 ng in 10 µl saline buffer) for 24 h. The neuroinflammation effect of sTNFα was evaluated through measure of the concentrations of kynurenine and tryptophan in the CSF as the kynurenine pathway of tryptophan metabolism was shown to mediate the action of pro-inflammatory cytokines, including sTNFα, in the brain [30][31][32] . Following the challenge with sTNFα, FVB animals expressing PrP C showed a ∼7-fold increase in the CSF [kynurenine]/[tryptophan] ratio, while PrP 0/0 -animals showed an exaggerated response with a ∼17-fold elevation of the [kynurenine]/[tryptophan] ratio (Fig. 5c). This suggests that in the absence of PrP C excessive TNFR1 signaling combined with deficit of the anti-inflammatory sTNFR1 factor caused by PDK1 overactivation would exacerbate the pro-inflammatory action of sTNFα in the brain. Accordingly, we showed that PDK1 inhibition and subsequent restoration of TNFR1 shedding (Fig. 5b) reversed the exaggerated kynurenine response induced by sTNFα icv injection in FVB PrP 0/0 mice (Fig. 5c).
As a whole, these in vivo data indicate that loss of PrP C is associated with a defect of TNFR1 shedding, which in turn exacerbates cell sensitivity to sTNFα-mediated inflammation.

Discussion
Although corruption of normal function(s) of cellular prion protein (PrP C ) plays a central role in TSEs, PrP C role(s) remain(s) elusive. This study discloses that PrP C limits the sensitivity of cells to the pro-inflammatory cytokine sTNFα by restricting the level of TNFR1 present at the plasma membrane. Such protective action of PrP C towards TNFα toxicity depends on the signaling activity of PrP C (i) to stimulate the cleavage of TNFR1 and the release of soluble TNFR1 (sTNFR1) through PrP C coupling to the NADPH oxidase-TACE α-secretase pathway and (ii) to ensure active TACE bioavailability at the plasma membrane through negative control of β1 integrin coupling to ROCK-I and PDK1 kinases.
PrP C acts as a signaling molecule at the cell surface and activates diverse effectors involved in neuronal homeostasis, including NADPH oxidase and TACE α-secretase 5,8,9 . Through coupling to the NADPH oxidase-TACE pathway, PrP C promotes the release of sTNFα into the cell microenvironment 9,33 . With 1C11-derived neuronal cells, sTNFα behaves as an autocrine modulator of neurotransmitter-associated functions devoid of any toxicity 9 . Here, we describe that PrP C also takes part to the regulated cleavage of transmembrane TNFR1 and the subsequent release of sTNFR1 into the cell microenvironment through TACE activation. The identification of Immunoprecipitation of ROCK-I followed by PDK1 western-blotting indicating reduced ROCK-I and PDK1 interaction in PrP null -1C11 cells treated with neutralizing β1 integrin antibodies. # p < 0.05. (c) Neutralization of β1 integrins in PrP null -1C11 cells decreases phosphorylation of PDK1 as assessed by 32 P metabolic labeling followed by PDK1 immunoprecipitation and western-blotting. # p < 0.05. (d) PDK1 activity returns to basal level in PrP null -1C11 cells exposed to MAB 1965 antibodies. *p < 0.01 vs. 1C11 cells. **p < 0.01 vs. untreated PrP null -1C11 cells. (e) Reduced sTNFα-induced caspase-3 activation in PrP null -1C11 5-HT cells exposed to MAB 1965 antibodies for 4 h. # p < 0.05 vs. PrP C expressing 1C11 5-HT -cells exposed to sTNFα. ## p < 0.05 vs. PrP null -1C11 5-HT cells treated with sTNFα. Data shown are the mean ± SEM from three experiments performed in triplicate.
Scientific RePoRTS | 7: 7671 | DOI:10.1038/s41598-017-08110-x TNFR1 as a novel target of the PrP C /NADPH oxidase/TACE coupling sheds light on how PrP C fine-tunes the cell response to sTNFα. By controlling the levels of shed TNFα and plasma membrane TNFR1, PrP C thus confines the role of sTNFα to modulation of neuronal functions. Accordingly, due to the peculiar binding stoichiometry between sTNFR1 and sTNFα (2:3), sTNFR1 molecules released by PrP C signaling (3000 molecules per 1C11 5-HT cell) neutralize PrP C -induced shed TNFα (4000 molecules per 1C11 5-HT cell) present in the cell microenvironment and, thereby, help to limit neuronal sTNFα signaling 34 . Dual control of TNFα release and TNFR1 shedding by TACE was also reported to protect liver from lipopolysaccharide (LPS)-induced inflammatory injury 35 . The present study also shows that the PrP C /TACE-mediated TNFR1 shedding ensures cell protection against an exogenous sTNFα insult with increased sensitivity of PrP null -cells and PrP 0/0 mice towards sTNFα. This is in line with increased vulnerability of PrP 0/0 mice to LPS-induced septic shock compared to PrP C expressing mice 2 associated with hyperactive inflammatory responses 36 . Our data add to the global idea that PrP C exerts stress protection in a physiological context [37][38][39][40] by adjusting the cell response to sTNFα of endogenous or exogenous origin.
We further evidence that the protective role of PrP C towards sTNFα also depends on its capacity to maintain TACE α-secretase at the plasma membrane. The rise of sensitivity of PrP null -cells to exogenous sTNFα is associated with an increased level of TNFR1 molecules present at the plasma membrane caused by deficit of TACE activity. From a mechanistic point of view, defect of TACE shedding activity in PrP null -cells originates from the displacement of TACE from the plasma membrane to intracellular compartments. The internalization of TACE in the absence of PrP C depends on a gain of plasma membrane β 1 integrin signaling. Lowering β 1 integrin activity in PrP null -cells directs TACE back to the plasma membrane and rescues TACE-mediated TNFR1 shedding. Acting as a scaffolding protein, PrP C limits β1 integrin microclustering at the plasma membrane and negatively regulates β 1 integrin signaling 6 . We further show that in the absence of PrP C excessive β1 integrin signaling and downstream ROCK-I overactivity promote overactivation of PDK1, which in turn triggers TACE internalization. Our work thus supports the view that PrP C cytoprotective effect against sTNFα toxicity is intimately linked to functional interactions between PrP C and β1 integrin.
In prion diseases, it is now widely acknowledged that the subversion of PrP C normal functions by PrP Sc takes a critical part in neuronal cell demise [41][42][43][44][45] . Whether loss of PrP C function upon its conversion into PrP Sc or gain of PrP C function by PrP Sc lies at the root of neurodegeneration is still debated. The phenotypic proximity of PrP null -cells with prion-infected cells lends support for loss-of-PrP C cytoprotective role towards TACE-mediated TNFR1 shedding along TSEs. Of note, is the increased sensitivity to sTNFα toxicity related to plasma membrane TNFR1 overexpression 13 highly comparable between PrP null -and prion-infected cells. Correlatively, the overactivation of ROCK-I and PDK1, as well as subsequent internalization of TACE 13, 21 occur with comparable intensities between PrP C -depleted and prion-infected cells. Such a loss-of-PrP C cytoprotective function towards inflammation in TSEs is further supported in vivo by increase in PDK1 activity and deficit of TNFR1 shedding in the brain of PrP 0/0 mice (Fig. 5a,b), as for prion-infected mice 13 . The exaggerated sensitivity to sTNFα-induced inflammation can be reversed upon PDK1 inhibition similarly between PrP 0/0 mice (Fig. 5c) and prion-infected mice 13 .
Contrasting with other amyloid-based neurodegenerative diseases, inflammation in TSEs is atypical-qualified 46 with low levels of inflammatory cytokines (sTNFα, IL1, IL6) released by activated microglia 47,48 in response to diverse signals emitted by prion-infected neurons 49 . Our data support the view that abrogation of PrP C cytoprotective function against sTNFα by PrP Sc is a priming event that renders prion-infected neurons sensitive to low doses of sTNFα. In line with this, the quickened death of prion-infected mice challenged with LPS 50, 51 could be due to an accelerated degeneration of TNFR1 overexposing infected neurons provoked by the LPS-induced release of sTNFα by reactive microglial cells or peripheral production of sTNFα.

Mice. Adult wild type FVB and
Scientific RePoRTS | 7: 7671 | DOI:10.1038/s41598-017-08110-x Neuronal dysfunction in CGNs and PrP 0/0 -CGNs was evaluated by sTNFα-induced dendritic fragmentation. CGNs and PrP 0/0 -CGNs seeded (5.10 5 cells per well) in 12-well plates coated with polyD-lysine (Sigma-Aldrich, St. Louis, MO, USA) were exposed to sTNFα. Cells were then fixed and stained with an anti-MAP2 antibody. After imaging with a fluorescence microscope (Zeiss Leica), cells exhibiting fragmented vs. non-fragmented dendrites were counted using ImageJ software (http://rsb.info.nih.gov/ij). Immunofluorescent experiments. Immunofluorescent labelings of PrP C , TNFR1, TACE and MAP2 were performed using standard protocols. Briefly, for cell surface detection of PrP C , TNFR1 and TACE, cells grown on glass coverslides were washed with cold PBS and fixed with 3.6% formaldehyde. Cells were incubated for 1 h at room temperature with the primary antibody in blocking buffer (PBS enriched with 2% FCS) and then with AlexaFluor 488-conjugated secondary immunoglobulins (1 µg ml −1 ; Molecular Probes, Eugene, OR, USA). For the intracellular detection of TACE or MAP2, cells fixed with 3.6% formaldehyde were permeabilized with 0.05% saponin or 0.1% Triton X-100, respectively, in PBS for 15 min at room temperature prior TACE or MAP2 immunostaining. Cell preparations were mounted under coverslips with Fluoromount G (Fisher Scientific, Pittsburgh, PA, USA) and analyzed by wide-field indirect immunofluorescence using a Leica DMI6000 B microscope (Wetzlar, Germany). For all images, out-of-focus haze was reduced by digital deconvolution of sets of 16 serial optical sections recorded at 0.3 µm intervals using the Adaptative Blind Deconvolution in the program Autoquant X (Meyer Instruments, Houston, TX, USA). All pixel values in each focal plane were then summed along z-axis to obtain the final image. Deconvoluted images were subjected to image analysis with the AQUA software 54 . PrP C silencing and enzyme inhibition. We exploited 1C11 precursor cells stably expressing shRNA towards PrP C in which PrP C expression is repressed by more than 90% (referred to as PrP null -1C11 cells) 6 . Because PrP null -1C11 cells fail to implement a neuronal phenotype upon exposure to serotonergic inducers 6 , 1C11 cells were converted into serotonergic 1C11 5-HT neuronal cells and then transfected with a siRNA against PrP C 41 using lipofectamine 2000 reagent following manufacturer's instructions (Invitrogen, Carlsbad, CA, USA). These cells refer to as PrP null -1C11 5-HT cells.
Immunoelectron microscopy. Cells, grown to ~80% confluency, were rinsed twice with PBS, collected in PBS and 10 mM EDTA, and rinsed twice with PBS. The cell pellet was fixed with 0.2% phosphate-buffered glutaraldehyde for 20-120 s and blocked with bovine albumin. Processing of cells for ultrathin cryosectioning and immunolabeling was performed indirectly 55 , with 5-or 7-nm gold particles conjugated with affinity-purified goat anti-mouse or anti-rabbit IgG (Invitrogen, Carlsbad, CA, USA) 56 . The labeled specimens were negatively stained with sodium silicotungstate, and images were captured with a JEOL CX100 transmission electron microscope.

ROCK-I immunoprecipitation.
ROCK-I immunoprecipitation was performed according to standard protocols by using protein A-Sepharose beads (Amersham Pharmacia Biotech, Picataway, NJ, USA) coupled to anti-ROCK-I antibody and 100 μg of cell lysates or brain extracts. Immunoprecipitates were analyzed by western blotting using anti-ROCK-I and anti-PDK1 antibodies.
Cell metabolic labeling with [ 32 P]-orthophosphate. [ 32 P]-orthophosphate labeling was performed as in ref. 57. Briefly, the cell culture medium was removed and cells were thoroughly washed with phosphate-free DMEM to eliminate any residual phosphate containing medium. [ 32 P]-orthophosphate (40.7 Gbq mmol −1 , GE Healthcare, Little Chalfont, UK) was added to the cell culture at a final concentration of 18.5 Mbq ml −1 . After 2 h, the labeling medium was removed and the cells were lyzed after extensive washing.
Measurement of PDK1 activity. PDK1 activity was measured in cell lysates or brain extracts using a fluorescent-labeled PDK1 substrate (5FAM-ARKRERTYSFGHHA-COOH, Caliper Life Sciences, Hanover, MD, USA) 58 . The relative amounts of substrate peptide and product phospho-peptide were determined using a Caliper EZ-reader (Caliper Life Sciences, Hanover, MD, USA).