- Research article
- Open Access
Microglial Cx3cr1knockout reduces prion disease incubation time in mice
BMC Neuroscience volume 15, Article number: 44 (2014)
Microglia are resident mononuclear phagocytes of the brain that become activated in response to insults including neurodegenerative diseases such as Alzheimer’s disease, Parkinson’s disease and prion disease. In the central nervous system the chemokine Cx3cl1 (Fractalkine) is expressed by neurons and its exclusive receptor Cx3cr1 is expressed solely on microglia. Cx3cl1/Cx3cr1 signalling is thought to maintain microglia in their resting state and disrupting this equilibrium may allow microglia to become activated. In prion disease, microglial proliferation has been suggested to contribute to overall disease progression, however, in different mouse models of neurodegeneration, loss of Cx3cr1 has been shown to either worsen or improve the phenotype depending on the paradigm.
To investigate the role of Cx3cl1/Cx3cr1 signalling in prion disease we infected Cx3cr1 null mice with three different strains of prions. Following challenge with Chandler/RML, ME7 and MRC2 prion strains, Cx3cr1 knockout mice showed highly significant reductions in incubation time. No differences were seen in the pattern and localisation of activated microglia in the brain or in the mRNA expression levels of chemokines/cytokines (Cxcl10, Il-12b, Il-1b, Arg-1 and Cxc3l1).
Our data suggest a protective role for Cx3cl1/Cx3cr1 cross-talk in prion disease.
Neuroinflammation within the brain is a common feature of neurodegeneration and one of the hallmarks of these changes is the activation of microglia. Microglia are CNS (central nervous system) mononuclear phagocytes that under normal conditions are surveillant but are activated in response to various brain insults [1, 2]. Activation can result in phagocytosis and the release of substances such as neurotrophic factors and cytokines/chemokines . While some of these functions are likely to be beneficial, it has been proposed that an excess of particularly proinflammatory cytokines may be damaging and that this immune response may contribute to disease pathogenesis.
Neurons express the chemokine Cx3cl1 (fractalkine) in a membrane bound or soluble form. Its receptor within the CNS, Cx3cr1, is expressed solely on microglia [4–6]. Cx3cl1 is thought to act as a chemoattractant recruiting microglia to sites of injury and the normal signalling between Cx3cl1 and Cx3cr1 is thought to provide part of the neuronal-microglial cross talk that maintain microglia in their resting state .
The role of Cx3cr1 has been extensively studied in many models of neurodegeneration and brain injury through the use of Cx3cr1 knockout mice, although often with conflicting results. In a triple transgenic (3xTg: PS1M146V knock-in, transgenic APP Swe and tauP301L) model of Alzheimer’s disease (AD) it was shown that loss of Cx3cr1 resulted in the increase of microglial migration and prevented neuronal loss while levels of Aβ deposition remained unaltered . The effect of Cx3cl1/Cx3cr1 signalling seen in the 3xTg model contrasts with the findings reported for both the APPPS1 and R1.40 models of AD where loss of Cx3cr1 altered microglial activation and reduced Aβ deposition . Knockout of Cx3cr1 in a toxin-induced model of Parkinson’s disease (PD) and a genetic model of Amyotrophic Lateral Sclerosis (ALS) (Tg SOD1G93A) worsened the phenotype, in both cases producing more neuronal loss and, for the ALS model, accelerated deterioration of hind limb grip function and reduced survival were also seen . In related experiments with a toxin-induced model of PD in rats, treatment with the ligand Cx3cl1 was neuroprotective with reduced microglial activation . In addition, in a model of tauopathy, a humanised MAPT transgenic mouse also lacking Cx3cr1 showed altered microglial activation, enhanced tau phosphorylation and aggregation as well as poorer spatial working memory . In contrast, smaller infarcts and better functional recovery was seen in the absence of Cx3cr1 in a model of ischaemia .
Prion diseases or transmissible spongiform encephalopathies (TSEs) are progressive neurodegenerative diseases that include Creuzfeldt-Jakob disease (CJD) in humans, bovine spongiform encephalopathy (BSE) in cattle and scrapie in sheep . In common with many other neurodegenerative diseases, a key feature of prion diseases is the accumulation of aggregates of an abnormally folded protein. In prion diseases these misfolded protein aggregates propagate by the conversion of normal cellular prion protein (PrPC) to abnormal isoforms, designated PrPSc and constitute lethal infectious agents. Prion infection is accompanied by spongiform change and neuronal loss in the brain. In contrast to other infectious diseases little if any evidence of inflammation is seen in the periphery. However, even before significant neuronal loss occurs, there is widespread activation of microglia, glia and astrocytes in the brain [14–16]. Proinflammatory cytokines increase during disease progression, however, this is greatly reduced relative to that seen during bacterial or viral infections [15, 17].
In wild type mice infected with a mouse-adapted scrapie prion strain (ME7) Cx3cl1 is reported to be upregulated in astrocytes but there is no change in surviving neurons and Cx3cr1 expression is also upregulated on microglia . Analysis of hamster brains infected with the prion strain 263K showed that Cx3cl1 is downregulated during disease progression . These data, together with the prominence of activated microglia early in prion disease and the parallels with other neurodegenerative disorders, suggest that Cx3cl1/Cx3cr1 signalling may play an important role in prion disease pathogenesis. To evaluate this hypothesis we challenged Cx3cr1 knockout mice with three different prion strains . Our results show that for two mouse-adapted scrapie strains (Chandler/RML and ME7) and a mouse-passaged BSE strain (MRC2), Cx3cr1 deficiency shortens the incubation time thereby suggesting that Cx3cl1/Cx3cr1 signalling is partially protective in prion disease.
Cx3cr1+/- mice (Cx3cr1/GFP, C.129P2-Cx3cr1tm1Litt/leg) on a Balb/c background were obtained as embryos from the European Mouse Mutant Archive, resurrected and bred to homozygosity . Wild type Balb/cOlaHsd mice were purchased from Harlan, UK Ltd (Bicester, UK).
Inocula for three different prion strains were made from the brains of terminally sick mice as 1% (weight/volume) homogenates in sterile D-PBS. Chandler/RML (I9900) and ME7 (I9459) are two different mouse-adapted strains of scrapie and MRC2 (I9468) is a mouse-passaged strain of BSE [19, 20]. Following anaesthesia with isofluorane/O2, female mice were inoculated intra-cerebrally with 30 μl of inocula into the right parietal lobe as previously described . Mice were examined daily for clinical signs of prion disease and were culled once a definitive diagnosis had been made or earlier if showing any signs of distress or excessive weight loss. Diagnostic signs of clinical prion disease include ataxia, impaired righting reflex and a sustained hunched posture . Incubation time was defined as the number of days from inoculation to confirmed diagnosis. The Kaplan-Meier log-rank test was used to analyse survival data using the statistical package SPSS (IBM). Animals were housed, maintained and cared for in accordance with institutional, UK and international regulations and standards on animal welfare and conform to ARRIVE guidelines . Ethical approval was granted by the Medical Research Council Prion Unit animal research ethics committee and carried out under UK Home Office licence PPL70/7274.
Neuropathology and immunohistochemistry
Mouse brains were fixed in 10% buffered formal saline (BFS) and prion-infected tissue was treated in 98% formic acid for one hour to remove infectivity. Tissues were paraffin wax embedded, sagitally sectioned and stained as previously described . Haematoxylin and eosin (H&E) stained sections were assessed to determine the relative levels and distribution of spongiosis and neuronal loss. Prion deposition was evaluated with the anti-PrP monoclonal antibody ICSM35 (D-Gen Ltd, UK) and gliosis was determined with an anti-glial fibrillary acid protein (GFAP) antibody (Dako Ltd, UK). Microglia were visualised by staining with an anti-Iba1 polyclonal antibody (Wako).
RNA was extracted using a TRIzol Plus RNA Purification kit (Life Technologies) from half brains taken from terminally sick prion infected mice and uninfected controls (n = 4 or 5 per group). cDNA was generated using a QuantiTect Reverse Transcription Kit (Qiagen). Contaminating genomic DNA was removed during the extraction with a DNase I digestion and this was confirmed by including a no reverse-transcription control for each sample. Real-time RT-PCR reactions were carried out using Taqman Gene Expression Master Mix enzyme (Life Technologies) on a 7500 Fast Real-time PCR System (Life Technologies). Gene specific Taqman Gene Expression assays (Life Technologies) were used for Cxcl10, Il-12b, Il-1b, Arg-1 and Cx3cl1. Each reaction was duplexed independently with two endogenous controls (rodent GAPDH and mouse β-actin, Life Technologies). All reactions were carried out in triplicate. Statistical tests were carried out using GraphPad InStat (GraphPad Software, Inc, California, USA).
Transmission of prions to Cx3cr1-/-mice
Cx3cr1 knockout mice were generated by replacing the Cx3cr1 gene with the green fluorescent protein (GFP) reporter gene . The gene targeting results in the loss of the wild type Cx3cr1 mRNA transcript and the generation of a chimeric transcript of an untranslated Cx3cr1 exon spliced to the GFP exon. The mice have a normal lifespan with no visible abnormal phenotype. The presence of GFP has not been reported to interfere with microglial function and microglia are still able to become activated in the absence of Cx3cr1 . To investigate the role of Cx3cl1/Cx3cr1 neuronal-glial cross talk in prion disease we inoculated female Cx3cr1-/- mice and Balb/c wild type controls intracerebrally with three different mouse-adapted prion strains. Chandler/RML and ME7 are two distinct scrapie-derived prion strains and MRC2 was generated from the passage of cattle BSE in mice [19, 20]. Each of these prion strains transmits readily to wild type mice and produce a distinctive incubation time and patterns of PrPSc distribution, gliosis and spongiosis . Onset of diagnostic signs of prion disease was significantly earlier in Cx3cr1-/- mice relative to controls for all three prion strains (Figure 1). For Chandler/RML prions the mean incubation time (days ± sem) was reduced by 4% from 150 ± 2 in Cx3cr1+/+ to 144 ± 1 in Cx3cr1-/- mice (P = 0.004, Kaplan-Meier log rank survival) and for ME7 the mean incubation time was reduced by 7% from 178 ± 1 in Cx3cr1+/+ to 168 ± 1 in Cx3cr1-/- mice (P < 0.0001, Kaplan-Meier log rank survival). For MRC2 the mean incubation time was reduced by 7% from 206 ± 2 in Cx3cr1+/+ to 200 ± 1 in Cx3cr1-/- mice (P < 0.0001, Kaplan-Meier log rank survival).
Brain sections from terminally sick mice from each group were evaluated for evidence of neuropathological changes. Overall, for Chandler/RML inoculated mice, the patterns of spongiosis, gliosis and PrP distribution were the same for both wild type and Cx3cr1-/- groups. Even in the absence of Cx3cl1/Cx3cr1 signalling, microglia show extensive proliferation and based on morphology appear to be activated and similarly distributed to that seen in the controls (Figure 2). Similarly, for ME7 and MRC2 inoculated animals, no differences were seen in the patterns of spongiosis, gliosis, PrP and microglia distribution between Cx3cr1-/- and Cx3cr1+/+ groups (Figures 3 and 4). Neuropathological differences are seen between the three prion strains, however, these are characteristic of the strains and do not appear to have been influenced by loss of Cx3cr1.
Prion strains in mice are characterised by their incubation time, neuropathology and the biochemical properties of PrPSc. To evaluate the effect of Cx3cr1 knockout on the faithful maintenance of strain characteristics we examined the brains of infected animals by western blotting using the anti-PrP antibody ICSM35. No differences were seen in PrPSc type between Cx3cr1-/- and Cx3cr1+/+ animals (Additional file 1 and Additional file 2: Figure S1).
Cytokine mRNA expression
Based on immunohistochemical staining with Iba1, we saw no differences in microglial proliferation and distribution between Cx3cr1 knockout and wild type mice. The activation status of microglia may be inferred by the relative abundance of various cytokines and chemokines in the brain. In other models of neurodegeneration in the absence of Cx3cr1, alterations in the cytokine/chemokine environment has been observed [8, 11]. We therefore measured the mRNA levels, by real time RT-PCR, of various cytokines/chemokines in the brains of terminally sick mice for each of our three prion strains and in uninfected controls for both wild type and Cx3cr1 knockout mice. Firstly, we looked at levels of cytokines/chemokines known to be induced in prion disease (Cxcl10, Il-12b and Il-1b) . Cxcl10 expression was significantly increased in all three prion strains relative to uninfected controls with 5-fold increases for Chandler/RML and ME7 and a 15-fold increase for MRC2 (P < 0.01 for all prion strains, T-test). No significant differences were seen between knockout and wild type groups (Figure 5A). Il-12b expression was also significantly increased in all prion-infected groups (P < 0.05 for all prion strains). However, a 2-fold increase was seen in Cx3cr1-/- relative to Cx3cr1+/+ mice (P = 0.01) but only with the ME7 prion strain (Figure 5B). Il-1b expression was significantly increased in all prion-infected groups (P < 0.01 for all strains, T-test), however, no significant differences were seen between Cx3cr1-/- and wild type controls (Figure 5C). Microglia may be activated through either a classical (M1) or alternative (M2) pathway . Cxcl10 is a marker of the M1 pathway and Arg-1 is a marker of the M2 pathway. As described, Cxcl10 mRNA expression is induced equally in both Cx3cr1 knockout and wild type mice with all prion strains, however, no differences were observed for Arg-1 mRNA expression by mouse genotype or prion infection (Figure 5D). This suggests that the M1 microglia activation pathway is triggered by prion infection and this is not altered by loss of Cx3cr1. We also looked at Cx3cl1 (fractalkine) mRNA expression and saw no significant differences between Cx3cr1 knockout and wild type mice or between infected and uninfected groups (Additional file 1 and Additional file 3: Figure S2).
We have shown that Cx3cr1 deficiency results in an acceleration in the onset of the clinical signs of prion disease, as illustrated by shorter incubation times, with three different prion strains. These data suggest that in wild type animals intact Cx3cl1/Cx3cr1 signalling is partially protective and may act to somewhat restrain the microglial response. The difference in incubation time observed in knockout mice is quantitatively modest but highly statistically significant with a reduction of 4% for Chandler/RML and 7% for both ME7 and MRC2 prion strains and no overall differences observed in microglial activation either by neuropathology or cytokine/chemokine expression in terminally sick mice. These data suggest that Cx3cl1/Cx3cr1 signalling plays only a minor role in modulating microglial activation in prion disease.
Although microglial activation was unaltered in our study it is worth noting that for both neuropathological examination and cytokine/chemokine production, we looked only at brains from terminally sick animals. It is possible that microglia are activated earlier in the absence of Cx3cr1 but by end stage disease microglia are activated and distributed as seen in wild type mice. If microglia are activated earlier in Cx3cr1-/- mice the earlier exposure to neurotoxic factors may contribute to the earlier onset of clinical disease. We observed a 2-fold increase in Il-12b expression in Cx3cr1-/- relative to Cx3cr1+/+ mice (P = 0.01) but only with the ME7 prion strain which suggests a prion strain specific effect. Given that this was not observed with other proinflammatory cytokines or with the other prion strains it is difficult to assess the relevance of this finding.
The role of Cx3cl1/Cx3cr1 signalling in neurodegeneration is variable, highly dependent on the model used and the phenotype measured and probably reflects the nature of the neuroinflammatory response triggered by each disease process. Our data suggest that for prion disease the neuronal-microglia cross talk provided by this interaction is partially protective but is not sufficient to override other pathways of microglial activation or neuronal loss. The protective role of Cx3cl1/Cx3cr1 is also seen in models of AD (APPPS1 and R1.40), ALS (TgSOD1G93A), tauopathy and PD [8–11]. This suggests that different neurodegenerative diseases share common pathways that ultimately contribute to neuronal death and that the relative importance of each pathway is governed by the nature of the original insult.
We have demonstrated that loss of Cx3cr1 results in an acceleration of onset of prion disease with three distinct prion strains (Chandler/RML, ME7 and MRC2) suggesting that intact Cx3cl1/Cx3cr1 signalling is partially protective in prion disease. This occurs in the context of unchanged microglial activation, as assessed by cellular distribution and cytokine profiles. The role of Cx3cl1/Cx3cr1 signalling in different models of neurodegeneration is highly variable suggesting that its influence is dependent on the precise cytokine environment created by each disease process.
Amyotrophic lateral sclerosis
Buffered formal saline
Bovine spongiform encephalopathy
Central nervous system
Dulbecco’s phosphate buffered saline
Glial fibrillary acid protein
Green fluorescent protein
Haematoxylin and eosin
Normal cellular prion protein
Abnormal disease associated isoform of prion protein
Reverse transcriptase-polymerase chain reaction
Transmissible spongiform encephalopathy.
Geissmann F, Manz MG, Jung S, Sieweke MH, Merad M, Ley K: Development of monocytes, macrophages, and dendritic cells. Science. 2010, 327: 656-661. 10.1126/science.1178331.
Wolf Y, Yona S, Kim KW, Jung S: Microglia, seen from the CX(3)CR1 angle. Front Cell Neurosci. 2013, 7: 26.
Hanisch UK, Kettenmann H: Microglia: active sensor and versatile effector cells in the normal and pathologic brain. Nat Neurosci. 2007, 10: 1387-1394. 10.1038/nn1997.
Hughes PM, Botham MS, Frentzel S, Mir A, Perry VH: Expression of fractalkine (CX3CL1) and its receptor, CX3CR1, during acute and chronic inflammation in the rodent CNS. Glia. 2002, 37: 314-327. 10.1002/glia.10037.
Jung S, Aliberti J, Graemmel P, Sunshine MJ, Kreutzberg GW, Sher A, Littman DR: Analysis of fractalkine receptor CX(3)CR1 function by targeted deletion and green fluorescent protein reporter gene insertion. Mol Cell Biol. 2000, 20: 4106-4114. 10.1128/MCB.20.11.4106-4114.2000.
Kim KW, Vallon-Eberhard A, Zigmond E, Farache J, Shezen E, Shakhar G, Ludwig A, Lira SA, Jung S: In vivo structure/function and expression analysis of the CX3C chemokine fractalkine. Blood. 2011, 118: E156-E167. 10.1182/blood-2011-04-348946.
Fuhrmann M, Bittner T, Jung CK, Burgold S, Page RM, Mitteregger G, Haass C, LaFerla FM, Kretzschmar H, Herms J: Microglial Cx3cr1 knockout prevents neuron loss in a mouse model of Alzheimer’s disease. Nat Neurosci. 2010, 13: 411-413. 10.1038/nn.2511.
Lee S, Varvel NH, Konerth ME, Xu GX, Cardona AE, Ransohoff RM, Lamb BT: CX3CR1 deficiency alters microglial activation and reduces beta-amyloid deposition in two Alzheimer’s disease mouse models. Am J Pathol. 2010, 177: 2549-2562. 10.2353/ajpath.2010.100265.
Cardona AE, Pioro EP, Sasse ME, Kostenko V, Cardona SM, Dijkstra IM, Huang DR, Kidd G, Dombrowski S, Dutta R, Lee JC, Cook DN, Jung S, Lira SA, Littman DR, Ransohoff RM: Control of microglial neurotoxicity by the fractalkine receptor. Nat Neurosci. 2006, 9: 917-924. 10.1038/nn1715.
Pabon MM, Bachstetter AD, Hudson CE, Gemma C, Bickford PC: CX3CL1 reduces neurotoxicity and microglial activation in a rat model of Parkinson’s disease. J Neuroinflammation. 2011, 8: 9-10.1186/1742-2094-8-9.
Bhaskar K, Konerth M, Kokiko-Cochran ON, Cardona A, Ransohoff RM, Lamb BT: Regulation of tau pathology by the microglial fractalkine receptor. Neuron. 2010, 68: 19-31. 10.1016/j.neuron.2010.08.023.
Denes A, Ferenczi S, Halasz J, Kornyei Z, Kovacs KJ: Role of CX3CR1 (fractalkine receptor) in brain damage and inflammation induced by focal cerebral ischemia in mouse. J Cereb Blood Flow Metab. 2008, 28: 1707-1721. 10.1038/jcbfm.2008.64.
Collinge J: Prion diseases of humans and animals: their causes and molecular basis. Annu Rev Neurosci. 2001, 24: 519-550. 10.1146/annurev.neuro.24.1.519.
Betmouni S, Perry VH, Gordon JL: Evidence for an early inflammatory response in the central nervous system of mice with scrapie. Neuroscience. 1996, 74: 1-5. 10.1016/0306-4522(96)00212-6.
Perry VH, Cunningham C, Boche D: Atypical inflammation in the central nervous system in prion disease. Curr Opin Neurol. 2002, 15: 349-354. 10.1097/00019052-200206000-00020.
Gomez-Nicola D, Fransen NL, Suzzi S, Perry VH: Regulation of microglial proliferation during chronic neurodegeneration. J Neurosci. 2013, 33: 2481-2493. 10.1523/JNEUROSCI.4440-12.2013.
Tribouillard-Tanvier D, Striebel JF, Peterson KE, Chesebro B: Analysis of protein levels of 24 cytokines in scrapie-infected brain and glial cell cultures of mice differing in prion protein expression. J Virol. 2009, 83: 11244-11253. 10.1128/JVI.01413-09.
Xie WL, Shi Q, Zhang J, Zhang BY, Gong HS, Guo Y, Wang SB, Xu Y, Wang K, Chen C, Liu Y, Dong XP: Abnormal activation of microglia accompanied with disrupted CX3CR1/CX3CL1 pathway in the brains of the hamsters infected with scrapie agent 263K. J Mol Neurosci. 2013, 51: 919-932. 10.1007/s12031-013-0002-z.
Grizenkova J, Akhtar S, Hummerich H, Tomlinson A, Asante EA, Wenborn A, Fizet J, Poulter M, Wiseman FK, Fisher EM, Tybulewicz VL, Brandner S, Collinge J, Lloyd SE: Overexpression of the Hspa13 (Stch) gene reduces prion disease incubation time in mice. Proc Natl Acad Sci U S A. 2012, 109: 13722-13727. 10.1073/pnas.1208917109.
Lloyd S, Linehan J, Desbruslais M, Joiner S, Buckell J, Brandner S, Wadsworth JD, Collinge J: Characterization of two distinct prion strains derived from bovine spongiform encephalopathy transmissions to inbred mice. J Gen Virol. 2004, 85: 2471-2478. 10.1099/vir.0.79889-0.
Lloyd S, Onwuazor ON, Beck J, Mallinson G, Farrall M, Targonski P, Collinge J, Fisher E: Identification of multiple quantitative trait loci linked to prion disease incubation period in mice. Proc Natl Acad Sci U S A. 2001, 98: 6279-6283. 10.1073/pnas.101130398.
O’Shea M, Maytham EG, Linehan JM, Brandner S, Collinge J, Lloyd S: Investigation of Mcp1 as a quantitative trait gene for prion disease incubation time in mouse. Genetics. 2008, 180: 559-566. 10.1534/genetics.108.090894.
Kilkenny C, Browne WJ, Cuthill IC, Emerson M, Altman DG: Improving bioscience research reporting: the ARRIVE guidelines for reporting animal research. PLoS Biol. 2010, 8: e1000412-10.1371/journal.pbio.1000412.
Martinez FO: Regulators of macrophage activation. Eur J Immunol. 2011, 41: 1531-1534. 10.1002/eji.201141670.
We are grateful to Jackie Linehan and her staff for histology and Huda Al-Doujaily and Jonathan Wadsworth for preparation of inocula. We also thank Biological Services Facility staff for animal care and Ray Young and Richard Newton for preparation of figures. This work was funded by the UK Medical Research Council (MRC).
JC is a director and shareholder of D-Gen Limited, an academic spin-out company in the field of prion diagnosis, decontamination and therapeutics. D-Gen markets the monoclonal antibody ICSM35 used in this study.
SL planned the experiments; SA, GJ, and SL carried out the experimental work. SB and SL analysed the data; SL and JC wrote the manuscript. All authors read and approved the final manuscript.
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Grizenkova, J., Akhtar, S., Brandner, S. et al. Microglial Cx3cr1knockout reduces prion disease incubation time in mice. BMC Neurosci 15, 44 (2014) doi:10.1186/1471-2202-15-44
- Prion disease
- Incubation time