Correspondence to Linda Greensmith: l.greensmith{at}ion.ucl.ac.uk
Abstract
Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative condition characterized by motoneuron degeneration and muscle paralysis. Although the precise pathogenesis of ALS remains unclear, mutations in Cu/Zn superoxide dismutase (SOD1) account for 2025% of familial ALS cases, and transgenic mice overexpressing human mutant SOD1 develop an ALS-like phenotype. Evidence suggests that defects in axonal transport play an important role in neurodegeneration. In Legs at odd angles (Loa) mice, mutations in the motor protein dynein are associated with axonal transport defects and motoneuron degeneration. Here, we show that retrograde axonal transport defects are already present in motoneurons of SOD1G93A mice during embryonic development. Surprisingly, crossing SOD1G93A mice with Loa/+ mice delays disease progression and significantly increases life span in Loa/SOD1G93A mice. Moreover, there is a complete recovery in axonal transport deficits in motoneurons of these mice, which may be responsible for the amelioration of disease. We propose that impaired axonal transport is a prime cause of neuronal death in neurodegenerative disorders such as ALS.
Introduction
Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative condition characterized by progressive motoneuron degeneration (Brown, 1995; Shaw, 1999; Cleveland and Rothstein, 2001; Rowland and Shneider, 2001). Although the precise etiology of the disease remains unclear, mutations in the enzyme Cu/Zn superoxide dismutase (SOD1) are responsible for 20% of familial ALS cases (Rosen et al., 1993), and transgenic mice overexpressing human mutant SOD1 develop an ALS-like phenotype (Gurney et al., 1994; Wong et al., 1995). The pathological mechanisms that cause selective motoneuron degeneration in ALS remain unclear, but evidence suggests that disruptions in axonal transport may play a significant role (Williamson and Cleveland, 1999; Rao and Nixon, 2003; Jablonka et al., 2004). Indeed, defects in anterograde axonal transport are one of the earliest pathologies observed in SOD1 mice (Williamson and Cleveland, 1999).
Cytoplasmic dynein is a molecular motor involved in retrograde axonal transport along microtubules (Goldstein and Yang, 2000) and plays a central role in motoneuron survival. Mice with a mutation in the dynein heavy chain (Dnchc1 mutants termed Legs at odd angles mice [Loa]) show defects in retrograde axonal transport and motoneuron survival (Hafezparast et al., 2003). Inhibition of dynein-mediated axonal transport, by postnatal overexpression of the motor-protein dynamitin, also results in motoneuron degeneration (LaMonte et al., 2002). Furthermore, mutations in dynactin, a motor protein involved in dynein-mediated transport, have been identified in families with slowly progressive forms of ALS (Puls et al., 2003; Munch et al., 2004). Defects in dynein-dependent transport also reduce trafficking of activated Trks, resulting in degeneration of sensory neurons (Heerssen et al., 2004). Thus, impairments of dynein-mediated axonal transport result in neuron degeneration, although some reports suggest that impaired axonal transport may be beneficial (Couillard-Despres et al., 1998; Williamson et al., 1998; Kong and Xu, 1999, 2000).
We studied the consequences of crossing Loa mice bearing a mutation in cytoplasmic dynein with SOD1G93A mice. We examined whether interaction between mutant SOD1 and the dynein mutation would affect disease progression and life span in double-heterozygote (Loa/SOD1G93A) mice.
Results and discussion
Loa heterozygote female mice (n = 12) were crossed with SOD1G93A males (n = 10), producing four genetically distinct groups of littermates: wild-type (WT), Loa heterozygotes, SOD1G93A hemizygotes, and Loa/SOD1G93A double heterozygotes. All mice were identified by genotyping for mutations in the Dnchc1 gene (Loa mutation) and the human SOD1 transgene, performed at 21 d and repeated in adults (>120 d).
We examined whether the mutation in cytoplasmic dynein, inherited from Loa mice, altered the life span of SOD1G93A mice (Fig. 1 a). As previously reported, Loa/+ mice had a normal life span (Hafezparast et al., 2003) and SOD1G93A mice a significantly reduced life span of only 125 d (± 2.5 SEM, n = 20), with disease end-stage defined as a loss of the righting reflex and 20% body weight. Surprisingly, Loa/SOD1G93A mice lived for 160 d (± 3.1 SEM, n = 18), an increase in life span of 28% (P 0.001). Disease onset was also delayed in Loa/SOD1G93A mice (see Online supplemental material for description of disease progression and Videos 1 and 2; available at http://www.jcb.org/cgi/content/full/jcb.200501085/DC1) with a significant delay in the loss of body weight (Fig. 1 b).
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The expression of the human SOD1 protein was examined to ensure that the breeding protocol had not altered the expression levels of the SOD1 transgene. Spinal cords from each group were processed for immunocytochemistry and quantitative Western blot analysis (Fig. 1, ce). Human SOD1 was only present in spinal cords of SOD1G93A and Loa/SOD1G93A mice, and not WT or Loa/+ littermates, as would be predicted by their genotype. Expression levels of human SOD1 in the Loa/SOD1G93A mice and their SOD1G93A littermates were quantified by chemifluorescence (ECF) and chemiluminescent (ECL) systems followed by scanning for fluorescence and image analysis, using mouse SOD1 proteins and proliferating cell nuclear antigen (PCNA) as internal standards. We compared the relative fluorescence ratios of mutant SOD1 over mouse SOD1 or PCNA in each genotype with that of the other genotypes. There were no significant differences in these ratios, indicating that the expression levels of the mutant SOD1 protein in each group of mice was the same and was not reduced in Loa/SOD1G93A mice.
Disease phenotype and progression in each group of mice was also examined by in vivo physiological analysis of extensor digitorum longus (EDL), an ankle flexor muscle, in 120-d-old mice (Fig. 2). In Loa/+ mice at this stage EDL muscles produce a normal force, but in SOD1G93A mice they are significantly weaker (P 0.05). Surprisingly, in Loa/SOD1G93A mice the muscles are as strong as in WT mice (P = 0.213). Furthermore, changes in the contractile characteristics of EDL that occur during disease progression in SOD1G93A mice (Kieran et al., 2004) do not occur in Loa/SOD1G93A mice at this age. EDL is normally a fast-contracting muscle that fatigues rapidly when repeatedly stimulated, producing a characteristic fatigue pattern from which a fatigue index (F.I.) can be calculated. A F.I. approaching 1.0 indicates that a muscle is very fatigable. As can be seen in Fig. 2 and Table I, these characteristics change dramatically in SOD1G93A mice, and by 120 d EDL is a slow, fatigue-resistant muscle. These changes are reflected in alterations in the histochemical properties of the muscle fibers, which show an increase in oxidative capacity, staining darkly for the oxidative enzyme succinate dehydrogenase (Fig. S1, ad; available at http://www.jcb.org/cgi/content/full/jcb.200501085/DC1). In contrast, in 120-d Loa/SOD1G93A mice EDL retains its normal contractile and fatigue characteristics, with no change in muscle fiber phenotype.
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In common with many other neurodegenerative diseases, the molecular processes responsible for neuronal death in ALS remain largely unknown. Although the molecular mechanism by which the dynein mutation induces amelioration in Loa/SOD1G93A mice is still under investigation, it is clear that the specific impairment of the neuronal function of cytoplasmic dynein rescues the defect observed in SOD1G93A mice and produces a complete recovery of the axonal retrograde transport defect. This in turn may be responsible for the dramatic delay in disease progression and extension in life span observed in Loa/SOD1G93A mice.
Materials and methods
The experiments were performed under license from the UK Home Office (Animals Scientific Procedures Act 1986), following local ethical review.
Breeding protocol
Loa/+ heterozygote female mice (n = 12) were crossed with SOD1G93A males (n = 10) to produce four genetically distinct groups of littermates: WT, Loa/+ heterozygotes, SOD1G93A hemizygotes, and Loa/SOD1G93A double-heterozygote mice (Achilli et al., 2005). All mice were identified by genotyping for mutations in the Dnchc1 gene (Loa mutation; Hafezparast et al., 2003) and the human SOD1 transgene (Gurney et al., 1994) from tail DNA.
Assessment of muscle force and motor unit number
At 120 d of age, mice were anesthetized (4.0% chloral hydrate solution, 1 ml/100 g body weight, i.p.) and prepared for in vivo assessment of muscle force (Kieran and Greensmith, 2004). Isometric contractions were elicited by stimulating the nerve to EDL using square-wave pulses of a 0.02-ms duration and supramaximal intensity. Contractions were elicited by trains of stimuli at a frequency of 20, 40, and 80 Hz. Twitch, maximum tetanic tension, time to peak, and half-relaxation time values were measured. The number of motor units in both EDL muscles was assessed by applying stimuli of increasing intensity to the motor nerve, resulting in stepwise increments in twitch tension, due to successive recruitment of motor axons.
Fatigue test
EDL muscles were stimulated at 40 Hz for 250 ms every second and the contractions were recorded on a pen recorder (Multitrace 2; Lectromed). The decrease in tension after 3 min of stimulation was measured and the F.I. was calculated as (initial tetanic tension tetanic tension after stimulation)/initial tetanic tension. A F.I. approaching 1.0 indicates that the muscle is very fatigable.
Muscle histochemistry
EDL muscles were snap frozen and 10-µm serial cross sections were cut and stained for succinate dehydrogenase activity.
Motoneuron survival
After transcardial perfusion with 4% PFA, the lumbar region of the spinal cord was removed and serial 20-µm transverse sections were cut and stained with gallocyanin, a Nissl stain. The number of Nissl-stained motoneurons in the sciatic motor pool of every third section (n = 60) between the L2 and L5 levels of the spinal cord were counted. Only large, polygonal neurons with a distinguishable nucleus and nucleolus and a clearly identifiable Nissl structure were included in the counts.
Immunocytochemistry
Sections of spinal cord were immunostained with antibodies to human SOD1 (1:500; Sigma-Aldrich) or glial fibrillary astrocytic protein (1:500; DakoCytomation) using standard protocols.
Microscopy, image acquisition, and manipulation
Spinal cord and muscle sections were examined at RT (22°C) under a light microscope (DMR; Leica) using Leica HC PL Fluotar objectives (10x/0.3, 20x/0.5 and 40x/0.7 magnification/NA). Images were captured using a digital camera (E995; Nikon) and the images downloaded into Adobe Photoshop CS. To optimize image contrast, Levels Adjustment operations were performed, but no other image manipulations were made.
Western blots
Total protein was determined in brain and spinal cord homogenates. NCL-SOD1 (Novocastra Laboratories Ltd.) and anti-PCNA (PC10, Santa Cruz Biotechnology, Inc.) were used to detect mouse/human SOD1 and PCNA proteins, respectively. For SOD1 protein quantification we used the ECF and ECL systems followed by scanning for fluorescence by a Storm-840 scanner (Molecular Dynamics) in three Western blots. Once scanned, the blots were analyzed using FragmeNT analysis software (Molecular Dynamics). Mouse SOD1 and PCNA proteins were used as internal standards to compare the relative amount of mutant SOD1 in each genotype.
Statistical analysis
Statistical significance was assessed between groups using a Kruskal-Wallis test followed by a Mann-Whitney U-test.
Axonal retrograde transport assay
Cysteine-tagged TeNT HC was labeled with AlexaFluor 488 maleimide (Lalli et al., 2003), and contained 1.8 mol of dye per mol of TeNT HC. Single embryo cultures enriched in motoneurons were obtained from E13 spinal cords, followed by DNase incubation and centrifugation through a 4% BSA cushion (Arce et al., 1999). This BSA solution was dialyzed for 24 h at 4°C against PBS and 48 h against Leibovitz-15 medium (GIBCO BRL), pH 7.3, using Spectra/Por membranes with a 25-kD cut-off. Cells were resuspended in complete medium, plated onto poly-D,L-ornithine/laminincoated 35-mm glass-bottom dishes (MatTek) at a density of 60,000 cells/plate, and maintained in culture for 57d. Three independent litters were used for the isolation of motoneurons with the four genotypes described. Motoneurons were incubated with 40 nM TeNT HC-Alexa 488 in complete medium for 30 min at 37°C, washed three times with Dulbecco's minimum essential medium without phenol red, riboflavin, folic acid, and penicillin/streptomycin, and supplemented with 30 mM Hepes-NaOH, pH 7.3. Cells were placed in a humidified chamber maintained at 37°C and were imaged every 5 s with an inverted microscope (Diaphot 300; Nikon) equipped with a Nikon 100x, 1.3 NA Plan Fluor oil-immersion objective. Carrier tracking was performed on time-lapse sequences using Motion Analysis software (Kinetic Imaging). Only moving carriers that could be tracked for at least four time points were considered. The distance covered by a carrier between two consecutive frames (referred to as a single movement) was used to determine its speed. In the final analysis we only included embryos with 15 or more TeNT HC carriers. Statistical analysis and curve fitting were performed using Microsoft Excel. Kymographs were generated using MetaMorph (version 6.2r4) after rotation of the image stack to align the neuronal process vertically. 200 vertical single-line scans through the center of each process were plotted sequentially for every frame in the time series.
Online supplemental material
The appearance of a number of observable disease features in each group of mice is described in the online supplemental material. Fig. S1 shows the histopathogy of EDL muscles and spinal cord sections of WT, Loa/+, SOD1G93A, and Loa/SOD1G93A littermates. Fig. S2 shows displacement graphs of TeNT Hc carriers in axons of each cohort of littermates. Table S1 details the kinetic parameters of TeNT Hc compartments in motoneurons of each group of mice. Videos 1 and 2 show examples of 120-d SOD1G93A and Loa/SOD1G93A littermates, respectively. Videos 36 shows phase images and corresponding movies of TeNT HC carriers transported in motoneuron axons of mice from each group of mice. Online supplemental material available at http://www.jcb.org/cgi/content/full/jcb.200501085/DC1.
Acknowledgments
We are grateful to The Brain Research Trust, The Motor Neuron Disease Association, The Medical Research Council, and Cancer Research UK for support.
Submitted: 18 January 2005
Accepted: 14 April 2005
Achilli, F., S. Boyle, D. Kieran, R. Chia, M. Hafezparest, J.E. Martin, G. Schiavo, L. Greensmith, W. Bickmore, and E.M.C. Fisher. 2005. The SOD1 transgene in the G93A mouse model of amyotrophic lateral sclerosis lies on distal mouse chromosome 12. Amyotroph. Lateral Scler. Other Motor Neuron Disord. In press.
Arce, V., A. Garces, B. de Bovis, P. Filippi, C. Henderson, B. Pettmann, and O. deLapeyriere. 1999. Cardiotrophin-1 requires LIFRß to promote survival of mouse motoneurons purified by a novel technique. J. Neurosci. Res. 55:119126.[CrossRef][Medline]
Brown, R.H. 1995. Superoxide dismutase in familial amyotrophic lateral sclerosis: models for gain of function. Curr. Opin. Neurobiol. 5:841846.[CrossRef][Medline]
Cleveland, D.W., and J.D. Rothstein. 2001. From Charcot to Lou Gehrig: deciphering selective motor neuron death in ALS. Nat. Rev. Neurosci. 2:806819.[CrossRef][Medline]
Couillard-Despres, S., Q. Zhu, P.C. Wong, D.L. Price, D.W. Cleveland, and J.P. Julien. 1998. Protective effect of neurofilament heavy gene overexpression in motor neuron disease induced by mutant superoxide dismutase. Proc. Natl. Acad. Sci. USA. 95:96269630.
Goldstein, L.S., and Z. Yang. 2000. Microtubule-based transport systems in neurons: the roles of kinesins and dyneins. Annu. Rev. Neurosci. 23:3971.[CrossRef][Medline]
Gurney, M.E., H. Pu, A.Y. Chiu, M.C. Dal Canto, C.Y. Polchow, D.D. Alexander, J. Caliendo, A. Hentati, Y.W. Kwon, and H.X. Deng. 1994. Motor neuron degeneration in mice that express a human Cu,Zn superoxide dismutase mutation. Science. 264:17721775.[Medline]
Hafezparast, M., R. Klocke, C. Ruhrberg, A. Marquardt, A. Ahmad-Annuar, S. Bowen, G. Lalli, A.S. Witherden, H. Hummerich, S. Nicholson, et al. 2003. Mutations in dynein link motor neuron degeneration to defects in retrograde transport. Science. 300:808812.
Heerssen, H.M., M.F. Pazyra, and R.A. Segal. 2004. Dynein motors transport activated Trks to promote survival of target-dependent neurons. Nat. Neurosci. 7:596604.[CrossRef][Medline]
Jablonka, S., S. Wiese, and M. Sendtner. 2004. Axonal defects in mouse models of motoneuron disease. J. Neurobiol. 58:272286.[CrossRef][Medline]
Kieran, D., and L. Greensmith. 2004. Inhibition of calpains, by treatment with leupeptin, improves motoneuron survival and muscle function in models of motoneuron degeneration. Neuroscience. 125:427439.[CrossRef][Medline]
Kieran, D., B. Kalmar, J.R. Dick, J. Riddoch-Contreras, G. Burnstock, and L. Greensmith. 2004. Treatment with arimoclomol, a coinducer of heat shock proteins, delays disease progression in ALS mice. Nat. Med. 10:402405.[CrossRef][Medline]
Kong, J., and Z. Xu. 1999. Peripheral axotomy slows motoneuron degeneration in a transgenic mouse line expressing mutant SOD1 G93A. J. Comp. Neurol. 412:373380.[CrossRef][Medline]
Kong, J., and Z. Xu. 2000. Overexpression of neurofilament subunit NF-L and NF-H extends survival of a mouse model for amyotrophic lateral sclerosis. Neurosci. Lett. 281:7274.[CrossRef][Medline]
Lalli, G., and G. Schiavo. 2002. Analysis of retrograde transport in motor neurons reveals common endocytic carriers for tetanus toxin and neurotrophin receptor. p75NTR. J. Cell Biol. 156:233239.
Lalli, G., S. Gschmeissner, and G. Schiavo. 2003. Myosin Va and microtubule-based motors are required for fast axonal retrograde transport of tetanus toxin in motor neurons. J. Cell Sci. 116:46394650.
LaMonte, B.H., K.E. Wallace, B.A. Holloway, S.S. Shelly, J. Ascano, M. Tokito, T. Van Winkle, D.S. Howland, and E.L. Holzbaur. 2002. Disruption of dynein/dynactin inhibits axonal transport in motor neurons causing late-onset progressive degeneration. Neuron. 34:715727.[CrossRef][Medline]
Liu, J., C. Lillo, P.A. Jonsson, C. Vande Velde, C.M. Ward, T.M. Miller, J.R. Subramaniam, J.D. Rothstein, S. Marklund, P.M. Andersen, et al. 2004. Toxicity of familial ALS-linked SOD1 mutants from selective recruitment to spinal mitochondria. Neuron. 43:517.[CrossRef][Medline]
Munch, C., R. Sedlmeier, T. Meyer, V. Homberg, A.D. Sperfeld, A. Kurt, J. Prudlo, G. Peraus, C.O. Hanemann, G. Stumm, and A.C. Ludolph. 2004. Point mutations of the p150 subunit of dynactin (DCTN1) gene in ALS. Neurology. 63:724726.
Nagata, Y., K. Fujita, M. Yamauchi, T. Kato, M. Ando, and M. Honda. 1998. Neurochemical changes in the spinal cord in degenerative motor neuron diseases. Mol. Chem. Neuropathol. 33:237247.[Medline]
Pasinelli, P., M.E. Belford, N. Lennon, B.J. Bacskai, B.T. Hyman, D. Trotti, and R.H. Brown Jr. 2004. Amyotrophic lateral sclerosis-associated SOD1 mutant proteins bind and aggregate with Bcl-2 in spinal cord mitochondria. Neuron. 43:1930.[CrossRef][Medline]
Puls, I., C. Jonnakuty, B.H. LaMonte, E.L. Holzbaur, M. Tokito, E. Mann, M.K. Floeter, K. Bidus, D. Drayna, S.J. Oh, et al. 2003. Mutant dynactin in motor neuron disease. Nat. Genet. 33:455456.[CrossRef][Medline]
Rao, M.V., and R.A. Nixon. 2003. Defective neurofilament transport in mouse models of amyotrophic lateral sclerosis: a review. Neurochem. Res. 28:10411048.[CrossRef][Medline]
Reichardt, L.F., and W.C. Mobley. 2004. Going the distance, or not, with neurotrophin signals. Cell. 118:141143.[CrossRef][Medline]
Rosen, D.R., T. Siddique, D. Patterson, D.A. Figlewicz, P. Sapp, A. Hentati, D. Donaldson, J. Goto, J.P. O'Regan, and H.X. Deng. 1993. Mutations in Cu/Z superoxide dismutase gene are associated with familial amyotrophic lateral sclerosis. Nature. 362:5962.[CrossRef][Medline]
Rowland, L.P., and N.A. Shneider. 2001. Amyotrophic lateral sclerosis. N. Engl. J. Med. 344:16881700.
Shaw, P.J. 1999. Motor neurone disease. BMJ. 318:11181121.
Williamson, T.L., and D.W. Cleveland. 1999. Slowing of axonal transport is a very early event in the toxicity of ALS-linked SOD1 mutants to motor neurons. Nat. Neurosci. 2:5056.[CrossRef][Medline]
Williamson, T.L., L.I. Bruijn, Q. Zhu, K.L. Anderson, S.D. Anderson, J.P. Julien, and D.W. Cleveland. 1998. Absence of neurofilaments reduces the selective vulnerability of motor neurons and slows disease caused by a familial amyotrophic lateral sclerosis-linked superoxide dismutase 1 mutant. Proc. Natl. Acad. Sci. USA. 95:96319636.
Wong, P.C., C.A. Pardo, D.R. Borchelt, M.K. Lee, N.G. Copeland, N.A. Jenkins, S.S. Sisodia, D.W. Cleveland, and D.L. Price. 1995. An adverse property of a familial ALS-linked SOD1 mutation causes motor neuron disease characterized by vacuolar degeneration of mitochondria. Neuron. 14:11051116.[CrossRef][Medline]