Sarm1 deletion suppresses TDP-43-linked motor neuron degeneration and cortical spine loss

Amyotrophic lateral sclerosis (ALS) is a progressive and ultimately fatal adult motor neuron disease that causes inexorable paralysis of limb, bulbar and respiratory muscles. Patients may also demonstrate cognitive deficits in keeping with frontotemporal dementia (FTD). Current disease modifying approaches for ALS have only a modest effect on survival and new therapeutic agents are urgently required. Targeting the earliest stages in the neurodegenerative process holds the greatest promise for therapeutic advances.

In ALS, pathological studies demonstrate early peripheral denervation before ventral nerve root or motor neuronal cell body loss suggesting that degeneration starts at the nerve terminal and progresses retrogradely along the axon [20]. Indeed, distal corticospinal tract inflammatory changes [8, 37] and giant axonal swellings have been detected in spinal cords from ALS patients, suggesting early distal axonal degeneration [15, 53]. Similarly, mutant-SOD1 mice with ALS-like phenotypes exhibit presymptomatic muscle denervation and terminal axonal degeneration before anterior horn cell loss [20, 58]. Axonal transport also appears to fail early in ALS. This is suggested by accumulation of ubiquitinated proteins, phosphorylated neurofilaments, mitochondria and microtubules in proximal axons and anterior horn cells of ALS patients [83]. Mutations in proteins with axonal functions are linked to ALS, including SMN, dynactin and spatacsin [14, 54]. Given that the axon constitutes 99.9% of the volume of a motoneuron and therefore places great metabolic demands on the cell, it is perhaps unsurprising that axonal degeneration can be an early event in ALS, and thus an attractive target for therapeutic intervention.

Almost all ALS and as many as half of FTD cases are characterised by pathological ubiquitinated inclusions of TAR DNA-binding protein 43 kDa (TDP-43) [3, 52]. The identification of mutations of TDP-43 in patients with ALS and FTD demonstrates that TDP-43 plays mechanistic roles in neurodegeneration [2, 7, 39]. Disturbances in TDP-43 homeostasis have been shown to affect axonal function and TDP-43 aggregates may form early within motor axons [10]. Knocking down or overexpressing wild-type or mutant TDP-43 disrupts motor neuron axons and terminal arborisations in flies [16, 42, 44] and zebrafish [38, 41]. TDP-43 transgenic rodents demonstrate early changes in neuromuscular junction (NMJ) and axonal integrity [65, 73, 81, 85, 87]. TDP-43 also localises within presynaptic vesicles in motoneurons in human spinal cord [62] and in axons in vitro [38]. Furthermore, axonal injury causes striking redistribution of TDP-43 from the nucleus to the cytoplasm and axon [50, 63]. Collectively, these results highlight how aberrant homeostasis of TDP-43 can directly impair axonal physiology, potentially causing neurodegeneration.

Given the importance of axon degeneration in ALS, there has been great interest in trying to protect axons and synapses as a therapeutic approach. Following injury to a nerve, typically a cut or crush, the process of Wallerian degeneration ensues, leading to fragmentation of axon fibres distal to the injury site within 72 h. This fragmentation was long thought to be due to loss of trophic support from the cell body [80], but studies of the mutant mouse Wld^S (Wallerian degeneration slow) established Wallerian degeneration as a tightly regulated process separate and distinct from apoptosis of the cell body [46]. While wild-type axons start to degenerate from 36 h following axotomy, Wld^S axons remain intact for weeks and can still conduct action potentials [46]. Wld^S encodes a fusion protein with nicotinamide mononucleotide adenylyltransferase 1 (NMNAT1) activity, which compensates for the loss of the axonal NMNAT2 isoform, which has a short half-life and is rapidly depleted from axonal segments distal to the site of injury or when its supply is interrupted for other reasons such as axonal transport deficit [13, 25, 47].

Importantly, screening in Drosophila has identified Wallerian degeneration regulating genes, indicating the presence of an endogenous axonal auto-destruction pathway that is conserved in mammals [51, 55, 84]. The first of these genes to be identified, sterile alpha and TIR motif-containing 1 (encoding Sarm1), acts downstream of NMNAT2 loss to promote axon degeneration following axotomy [24, 26, 45, 55, 79]. In fact, the deletion of Sarm1 is significantly more protective than Wld^S overexpression in an Nmnat2 depletion model of neurodegeneration as mice age [27]. These observations confirmed that Wallerian degeneration is an active, genetically programmed process that can be potently inhibited.

Evidence to suggest that Wallerian-like processes occur in neurodegenerative diseases comes from recent studies in which the axon outgrowth and regeneration factor Stathmin 2 (also known as SCG10) was found to be downregulated in ALS spinal motor neurons [40, 49]. Loss of Stathmin 2 was previously shown to enhance Wallerian degeneration following axon transection [66]. Furthermore, impaired axonal mitochondrial function, an early pathophysiological event in ALS [67], activates the Wallerian pathway leading to Sarm1-dependent axonal degeneration [72]. Mechanistic studies have also shown, to varying degrees, that axonal protection can be neuroprotective. For example, mice lacking Sarm1 have improved functional outcomes as well as attenuated axonal injury following mild traumatic brain injury [31], while deletion of Sarm1 prevents chemotherapy induced peripheral neuropathy [23]. Wld^S can ameliorate axonopathy in models of Charcot-Marie-Tooth disease, Parkinson’s disease and glaucoma [5, 60, 61]. Wld^S is also protective in the progressive motor neuronopathy (pmn) mouse [18]. Although Wld^S has little effect on survival in mutant-SOD1 mice, it significantly protects NMJs in young G93A transgenic mice [19, 77]. Studies in C. elegans demonstrate that loss of the Sarm1 homolog Tir-1 suppresses neurodegeneration and delays paralysis induced by mutant TDP-43 [78]. Finally, the human SARM1 locus has also been associated with sporadic ALS risk [22]. Collectively, these observations suggest that Wallerian-like mechanisms could contribute to the neurodegeneration seen in motor neuron diseases, and that depletion of SARM1 could have therapeutic potential in ALS. However, there have been no studies in mammalian models that have investigated a link between Wallerian pathways and TDP-43-mediated neurodegeneration. This is a particularly important question as TDP-43 pathology is a hallmark of 98% of ALS, including sporadic ALS. We therefore sought to determine whether SARM1 signalling could be a therapeutic target in ALS by deleting Sarm1 from a TDP-43^Q331K transgenic mouse model of ALS-FTD. Our results demonstrate that Sarm1 deletion has a neuroprotective effect and leads to both improvements in motor axonal integrity and, importantly, lumbar motor neuron survival.

Here, we have shown that by deleting Sarm1 from a TDP-43^Q331K transgenic mouse model of ALS-FTD it is possible to significantly attenuate motor axon, NMJ and motor neuron cell body degeneration. Sarm1 deletion appeared to protect motor neuron cell bodies to a greater extent than motor axons, which were in turn protected more so than NMJs (compare Fig. 1c, e and 2c). An underlying mechanism for this could be that motor neurons are reliant on neurotrophic support from distal targets of innervation for continued survival [59, 64, 76]. By preserving the physical link between the cell body and the target muscle, Sarm1 deletion may improve cell body survival by helping to maintain retrograde trophic support. Collectively, these findings are in keeping with the hypothesis that ALS is a dying-back disease in which the most distal compartments of motor neurons (the NMJs and axons) are the most vulnerable in disease.

Importantly, our study design used Sarm1 hemizygosity to enable comparison with littermate controls without the need for an excessively large breeding program. The inability of Sarm1 hemizygosity to preserve severed sciatic nerves for up to 2 weeks supports this approach. However, it cannot be ruled out that Sarm1 hemizygosity is partially protective in some circumstances. This raises the possibility that in the present study we may be underestimating the protective capacity of Sarm1 deletion as we did not utilise mice that were Sarm1^+/+ as controls.

This study used a TDP-43^Q331K transgenic mouse previously described as a model of ALS [4]. Interestingly, we observed several characteristics that were not previously reported for this model and which are reminiscent of FTD. We noted that TDP-43^Q331K mice gained significant weight compared to NTG mice. Mutants were also strikingly cognitively impaired and demonstrated significant brain atrophy from an early stage. No weight gain or cognitive dysfunction was previously described in this mouse model [4]. These differences could be because mice bred for this study were on a different background to that previously described. Although food intake was not measured, the excessive weight gain that mutants displayed could be due to hyperphagia, which is a feature of human FTD, and which we previously described in TDP-43^Q331K knock-in mice [82]. It also remains possible that this weight gain is due to direct effects of TDP-43 overexpression on lipid metabolism [12, 70].

In keeping with findings in humans, MRI demonstrated prominent brain atrophy in areas corresponding to the temporal lobe in these mice, and we histologically corroborated a greater neuronal loss in the entorhinal cortex than in the motor cortex. This is interesting, because studies in humans have shown that the temporal lobe can be significantly affected in ALS patients even without clinical evidence of dementia or temporal lobe-specific dysfunction (Loewe et al. Sci Rep 2017). While this study found no evidence of changes in MD, decreased FA was detected in several white matter tracts further matching the tractography findings in human patients [56]. Small but significant increases in FA in the temporal grey matter regions that also feature volume loss are difficult to interpret, but may be linked to a combination of alterations in glial and fibre density [71]. Collectively, these observations suggest that this TDP-43^Q331K transgenic mouse recapitulates features of FTD as well as ALS.

Of particular relevance to FTD, mutant TDP-43 has previously been shown to cause cortical dendritic spine abnormalities that are associated with attenuated neuronal transmission [21, 29]. In keeping with this, our study revealed significant brain atrophy and dendritic spine loss in TDP-43^Q331K mice. Furthermore, our study is the first to demonstrate that this dendritic spine degeneration can be mitigated by deletion of Sarm1. This is notable as Wallerian and Wallerian-like degeneration has only previously been linked with axonal, NMJ and post-synaptic integrity. Our results now suggest that Wallerian pathways are relevant to post-synaptic compartments of neurons, although it is also possible that the increase in dendritic spines following Sarm1 deletion is secondary to the preservation of presynaptic nerve terminals that synapse onto the spines.

Interestingly, TDP-43^Q331K overexpression phenotypes show evidence of sexual divergence. This comes from the observation that during breeding, mutant mice were underrepresented amongst males but not females. This is in keeping with our previous observations in TDP-43^Q331K knock-in mice, in which mutant males but not females were present at a lower frequency than would be expected by Mendelian laws of inheritance [82]. These phenomena are also more generally consistent with the higher incidence of ALS in male patients [48, 75]. Furthermore, we also found that amongst males there were significantly more Q331K-Sarm1^−/− mice than Q331K-Sarm1^+/− mice (Fig. 1b). This suggests that TDP-43^Q331K influences nervous system development in a way that is attenuated by Sarm1 deletion. We speculate that this beneficial effect of Sarm1 deletion may occur in utero by influencing Wallerian-like degeneration in a manner similar to that observed during the rescue of CNS nerve tracts and peripheral nerve axons in embryos lacking Nmnat2 [26].

Despite the suppression of neurodegeneration by Sarm1 deletion, this was insufficient to cause behavioural improvements in TDP-43^Q331K overexpressing mice. This could be because this mouse model demonstrated very early and marked brain and muscle atrophy, which may be difficult to reverse. A similar explanation may underlie the apparent lack of efficacy of Sarm1 deletion in a mutant SOD1 mouse model of ALS, which demonstrates rapid disease onset and progression [57], and in our previous study in Drosophila in which even clonal TDP-43^Q331K overexpression causes early and aggressive neurodegeneration [69]. We speculate that under less extreme degrees of cellular disintegration, and in more physiological models, which are likely to be more reflective of early disease states in patients with ALS-FTD, Sarm1 deletion may have a greater ability to attenuate behavioural and motor dysfunction. Further support of this comes from human genome-wide studies that have identified an association between genetic variants at the human SARM1 locus and the risk of developing ALS [22]. It remains to be determined if these genetic variants influence SARM1 expression, but if so then this would further support a mechanistic link between TDP-43-mediated toxicity in sporadic ALS and Wallerian-like degeneration.

In conclusion, our results indicate that a Sarm1 dependent pathway contributes to TDP-43^Q331K-mediated motor neuron, motor axon, NMJ and cortical spine degeneration in vivo. Anti-SARM1 therapies therefore have potential as a treatment for diseases of the ALS-FTD spectrum.