Inhibition of colony-stimulating factor 1 receptor early in disease ameliorates motor deficits in SCA1 mice

Neuroinflammation, the brain’s response to injury, is associated with many neurodegenerative diseases, including Alzheimer disease (AD), Parkinson disease (PD), amyotrophic lateral sclerosis (ALS), multiple sclerosis (MS), Huntington disease (HD), and spinocerebellar ataxia type 1 (SCA1) [1‐7]. Emerging evidence suggests that neuroinflammation can actively contribute to disease pathogenesis [8‐11], but its role in disease is complex and includes both amelioration and promotion of disease progression. While different brain cell types contribute to neuroinflammation, microglia, the resident immune cells of the brain, are considered to be the primary mediators of neuroinflammation [12].

During brain development, microglia are responsible for the removal of synapses and apoptotic cells [13‐16]. In the healthy adult brain, microglia’s long processes actively sample brain environment for neuronal activity and signs of brain injury [17]. In a reaction to brain injury, microglia undergo morphological and functional changes, including enlargement of cell bodies and thickening of their processes and increased expression of pro-inflammatory cytokines. It has been proposed that the extent of microglial activation and thereby their contribution to the pathogenesis depends on the type and extent of injury [5]. For example, many studies have found chronically activated microglia to be harmful and worsen the disease outcome in ALS, HD, PD, and AD [8, 18‐23]. However, there are also studies that suggest activated microglia may be beneficial in these diseases [24‐31].

Spinocerebellar ataxia type 1 (SCA1) is a dominantly inherited neurodegenerative disorder characterized by progressive loss of motor coordination, cognitive impairments, and depression [32, 33]. SCA1 is caused by an expansion of glutamine-encoding CAG (Q) repeats in the gene Ataxin-1 (ATXN1) [34, 35]. There are eight other neurological diseases, including HD, that share the polyQ mutational mechanism [33]. One of the most intriguing characteristics of polyQ diseases is their limited pathology despite the widespread expression of disease-causing proteins. While ATXN1 is ubiquitously expressed, Purkinje neurons of the cerebellum are the most affected cells in SCA1 [36]. For this reason, most studies so far investigated Purkinje neuron-intrinsic pathology in SCA1. Recent evidence suggested that glial cells might also play a role in the pathogenesis of SCA1. Proton magnetic resonance spectroscopy studies suggested that gliosis correlates with disease severity in SCA1 patients, and we have recently demonstrated that microglia are activated early in several mouse models of SCA1 [4, 37]. However, whether and how microglia contribute to SCA1 is unknown. To study the role of microglia in SCA1, we reduced their numbers by using the pharmacological inhibition of colony-stimulating factor 1 receptor (CSF1R) signaling, which is essential for microglial survival. For this, we used PLX3397, inhibitor of CSF1R, referred to as “PLX” (Plexxicon Inc.), that has been shown to cause microglial depletion within several days of administration [38]. PLX also inhibits c-kit and Flt3 pathways, but few studies have shown their participation in SCA1. Mice treated with PLX for 2 months did not demonstrate any motor deficits or other abnormality, suggesting that long-term PLX administration is safe. We have focused our study on the early stages of SCA1 for several reasons. First, microglia are activated early in SCA1 mice. Second, studies in several neurodegenerative diseases, including SCA1, suggested that it is difficult to ameliorate disease pathology during the late stages after neuronal loss had already occurred [39]. Third, because SCA1 is an inherited disease, starting the treatment early is feasible. Fourth, microglia have recently been implicated in the early synaptic loss in Alzheimer disease; since loss of Purkinje cell synapses starts early in SCA1 as well, we reasoned that depleting microglia may ameliorate synaptic loss in SCA1 [8, 40, 41].

We have designed this study to test the role of the microglia during the early stages of disease in the transgenic mouse model of SCA1. Our data demonstrated that depleting microglia during the early stage improved motor deficits in SCA1 mice, suggesting that microglia may play an important role in the pathogenesis of SCA1. However, we did not detect a significant change in PN atrophy and synaptic loss treatment nor significantly altered astrogliosis, including changes in GFAP expression and rescue of gene expression changes in reactive astrocytes in SCA1 mice treated with PLX. These data may suggest that dysfunction of Purkinje neurons is sufficient to activate astrocytes in SCA1, or that remaining microglia can still cause astrogliosis, and other cerebellar glia, such as Bergman glia, may be able to remove synapses in absence of microglia.

We further investigated the molecular mechanisms underlying the ameliorated motor function, and we found that increased expression of PSD95 and ATXN1[2Q], and reduced pro-inflammatory cytokine TNFα expression with PLX treatment may be beneficial to alleviate pathogenesis of SCA1. Despite not finding changes in VGLUT2 climbing fiber synapses in PLX-treated SCA1 mice, the increase in the post-synaptic marker PSD95 may indicate a homeostatic mechanism to preserve the functions of remaining synapses. In addition, our data also showed that depleting microglia decreased expression of pro-inflammatory cytokine TNFα. This result suggests that, at least in ATXN1[82Q] mice, microglia produce the majority of TNFα, and that this decrease in TNFα in PLX-treated ATXN1[82Q] mice may contribute to improved motor function [54]. Intriguingly, PLX increased the level of wild-type Atxn1[2Q]. Previous studies have demonstrated that wild-type ataxin-1 is protective in SCA1. It has been demonstrated that polyQ mutation leads to both loss and gain of toxic function, and that reducing levels of wild-type ataxin-1 worsens SCA1 disease phenotype. Therefore, this increase in wild-type ataxin-1 may be beneficial and promote function of Purkinje neurons [52]. While the underlying mechanism by which PLX treatment results in increased ataxin-1 expression is unclear, it is possible that PLX may directly regulate ataxin-1 through c-kit and Flt3 signaling (also inhibited by PLX), or that microglia and neuroinflammation may modulate protein clearance in neurons in neurodegenerative disease.

Increasing evidence suggests that glial cells, including microglia, astrocytes, and oligodendrocytes, are critical for the functions of CNS, yet their roles in diseases and interactions with each other remain controversial. In many neurodegenerative diseases, including SCA1, microglia undergo morphological and functional changes, including enlargement of their cell bodies, thickening of their processes, and increased expression of pro-inflammatory cytokines [55‐57]. In this study, we have used the transgenic mouse model of SCA1 in which mutant protein is expressed only in Purkinje neurons. In these mice, microglia are activated in response to neuronal dysfunction only 1 week after the onset of the mutant ATXN1[82Q] expression in neurons. Such early activation of microglia in ATXN1[82Q] mice demonstrates that cerebellar microglia are closely tuned to neuronal dysfunction [4]. We have previously demonstrated that cerebellar astrocytes are also activated early in SCA1. Astroglia are critical for neuronal functions under non-pathological conditions, and Bergman glia (BG), a type of cerebellar astrocyte that interacts very closely with Purkinje neurons, perform many important physiological functions including regulation of ion homeostasis, uptake of released neurotransmitters, secretion of neurotrophic factors, and synaptic remodeling. In disease, astrocytes also undergo activation that results in morphological and functional changes, including enlarged cell bodies, thickening of cell processes, altered ability to maintain homeostasis of ions and neurotransmitters, and production of neurotrophic factors. Early in disease progression, astrocytes in SCA1 mice are enlarged and have increased expression of GFAP and astrocytic genes that regulate homeostasis and promote neuronal survival, such as Kir4.1. Microglia have the capacity to interact with astrocytes and thus modulate their activation. Because both astrocytes and microglia are activated around the same time in SCA1, it is possible that microglia contribute to activation of astrocytes. Since depletion of microglia did not significantly alter hallmark signs of astrogliosis, increase in GFAP expression, and only a trend towards change in astroglial gene expression, this result may indicate that either microglia do not modulate astroglial activation, or that remaining microglia are sufficient to modulate astrogliosis. Oligodendrocytes are myelinating cells of the CNS that also contribute to trophic support of neurons. While oligodendrocytes are critical during cerebellar development, and increasing evidence suggests that both oligodendrocyte precursor cells and oligodendrocytes can contribute to neuroinflammation and disease progression in many diseases [58‐61], very little is known about their role in SCA1. Future studies will explore whether oligodendrocytes are involved in SCA1. This is the first study to demonstrate that microglia contribute to the pathogenesis during the early stages of SCA1 by showing an amelioration of motor deficits when microglia are reduced early in disease. These results challenge the dogma that SCA1 is only a neuronal disease and provide evidence for the possibility of glia-based therapies for SCA1. We are intrigued by the observed increase in ataxin1 protein levels in Purkinje neurons after PLX treatment. While the underlying mechanism is not clear, this result may suggest that either normal function of microglia is to help regulate protein degradation in neurons or PLX directly modulates protein degradation in PN, acting through c-kit or Flt3. Identifying the molecular mechanism of this effect of PLX could provide novel therapies to prevent build up and aggregation of toxic proteins by enhancing protein degradation in neurons in SCA1 and other neurodegenerative diseases. It is important to note that microglial contribution to the pathogenesis of SCA1 may change with disease progression [5, 55]. Future studies testing the role of microglia in late stages of SCA1 could address this question.

We have found that PLX reduced the number of microglia and microglial gene expression, including expression of pro-inflammatory cytokine TNFα in the cerebella of wild-type and SCA1 mice. Importantly, PLX significantly improved the motor performance of SCA1 mice, suggesting a potential therapeutic benefit. PLX did not significantly alter astrogliosis, but showed trend towards modulation of astroglial gene expression. PLX treatment increased protein levels of wild-type ataxin-1, indicating a possible role of microglia and/or c-kit and Flt3 signaling in neuronal protein clearance.