Abstract
The cerebellum is crucial for sensorimotor coordination. The cerebellar architecture not only requires proper development but also long-term integrity to ensure accurate functioning. Developmental defects such as impaired neuronal migration or neurodegeneration are thus detrimental to the cerebellum and can result in movement disorders including ataxias. In this study, we identify FBXO41 as a novel CNS-specific F-box protein that localizes to the centrosome and the cytoplasm of neurons and demonstrate that cytoplasmic FBXO41 promotes neuronal migration. Interestingly, deletion of the FBXO41 gene results in a severely ataxic gait in mice, which show delayed neuronal migration of granule neurons in the developing cerebellum in addition to deformities and degeneration of the mature cerebellum. We show that FBXO41 is a critical factor, not only for neuronal migration in the cerebellum, but also for its long-term integrity.
Introduction
The cerebellum is known for its crucial role in motor control and coordination. The adult cerebellar cortex exhibits a characteristic foliated morphology and well defined architecture consisting of three major layers: the molecular layer, the Purkinje cell layer, and the granule layer (Altman and Bayer, 1997). To establish proper lamination and circuitry, important events such as neuronal differentiation, morphogenesis, and migration need to be precisely regulated during cerebellar development (Altman and Bayer, 1997; Komuro and Yacubova, 2003; Sillitoe and Joyner, 2007). Defects in cerebellar development are often associated with various disorders including Dandy-Walker Malformations, Joubert Syndrome, and other congenital ataxias (Zoghbi, 2000; Millen and Gleeson, 2008; Basson and Wingate, 2013).
Neuronal migration of granule neurons is one of the critical developmental events in the cerebellum that ensures properly timed lamination. During embryonic development, the rhombic lip gives rise to cerebellar granule neuron progenitors, which migrate rostrally to settle in the cerebellar anlage (Wingate, 2001). After a phase of proliferation, which results in expansion of the external granular layer, granule neuron precursors start migrating inward through the developing molecular layer past the Purkinje cell layer to ultimately take up residence in the internal granular layer (Altman and Bayer, 1997). Needless to say, these events require thorough and precise orchestration. A growing number of factors that contribute to the successful migration of granule neurons have been identified (Komuro and Yacubova, 2003; Sillitoe and Joyner, 2007). Recent additions to the list of regulators, such as profilin1, adenomatous polyposis coli 2, or various E2 ubiquitin-conjugating enzymes, give an indication of how delicate and complex granule neuron migration really is (Kullmann et al., 2012; Shintani et al., 2012; Heng et al., 2015; Kumazawa et al., 2013; Huang et al., 2014; Jaarsma et al., 2014; Anckar and Bonni, 2015; Sathyamurthy et al., 2015; Yong et al., 2015).
Neuronal migration is intimately linked to the centrosome, a critical site for microtubule nucleation (Solecki et al., 2006; Higginbotham and Gleeson, 2007). Among the hundreds of centrosomal proteins (Andersen et al., 2003), a subset regulates neuronal migration and is also functionally intertwined (Wynshaw-Boris and Gambello, 2001; Tsai and Gleeson, 2005; Higginbotham and Gleeson, 2007; Kuijpers and Hoogenraad, 2011; Ramahi and Solecki, 2014). In addition to centrosomal proteins, microtubule-binding proteins have critical roles in neuronal migration because they control microtubule elongation and retraction (Tsai and Gleeson, 2005; Vallee et al., 2009; Falnikar et al., 2011). Not surprisingly, various small GTPases that control cytoskeletal dynamics have also been implicated in neuronal migration (Govek et al., 2011; Kawauchi, 2011). Even though recent studies have characterized E3 ligases that regulate neuronal migration by acting upstream of the centrosomal proteins Par6α or Pard3a, the Reelin-regulated signaling component Dab1, or the small GTPase RhoA (Feng et al., 2007; Famulski et al., 2010; Kannan et al., 2012a; Kannan et al., 2012b; Vadhvani et al., 2013), E3 ligases remain poorly explored regulators of neuronal migration.
In this study, we identified the F-box protein FBXO41, a potential E3 ubiquitin ligase, as a neuron-specific protein in the CNS that plays a role in neuronal migration. We also characterized the novel FBXO41 knock-out mouse that displays an ataxia-like motor phenotype.
Materials and Methods
Ethical statement.
All experiments involving live animals were conducted in accordance with animal protocols approved by the Niedersächsisches Landesamt für Verbraucherschutz und Lebensmittelsicherheit (Lower Saxony, Germany).
Constructs.
N-terminally myc- or GFP-tagged mouse FBXO41 was cloned into pCMVmyc or pEGFP vectors, respectively. A DNA-based template method was used to express short hairpin RNAs in the U6/(cytomegalovirus) cmv-EGFP vector. The sequences 5′-GGGTGCCGGCATCGAGAAGGT-3′ and 5′-AGCTGCTGCCGTGCCCT-3′ were used to construct the FBXO41 RNAi#5 and #8 plasmids, respectively. The rescue plasmids for FBXO41 and FBXO41-ΔCTR were generated by introducing silent mutations into the RNAi-targeting regions using site-directed mutagenesis. FBXO41 deletion mutants were generated by standard and fusion PCR. For the latter, two separate PCRs were performed to amplify fragments A and B omitting the region to be deleted but introducing compatible overhangs into each fragment. Subsequently, another PCR was performed to fuse both fragments resulting in a protein lacking the desired region.
Antibodies.
Antibodies used in this study include γ-tubulin (Sigma-Aldrich), pan 14-3-3 (Santa Cruz Biotechnology), pericentrin 2 (Abcam), mouse monoclonal GFP (Santa Cruz Biotechnology), rabbit polyclonal GFP (Invitrogen), β-Gal (Santa Cruz Biotechnology), SnoN (Santa Cruz Biotechnology), GFAP (Promega), PLP [gift from Prof. K.A. Nave, Max Planck Institute (MPI) of Experimental Medicine, Göttingen, Germany], GFAP (Nova Castra), Iba1 (WAKO), calbindin (Sigma-Aldrich), parvalbumin (Swant), NeuN (Millipore), PCNA (Abcam), β-gal antibody (Santa Cruz Biotechnology), and cleaved caspase 3 (Cell Signaling Technology).
FBXO41 antibodies were raised in rabbit against recombinant His6-tagged rat FBXO41 (aa124–184) isolated from bacteria using Nickel-NTA Sepharose (IBA). Polyclonal serum, obtained from Eurogentec, was then affinity purified using recombinant rat FBXO41 protein bound to amino link plus columns.
Primary neuron culture, transfections, and immunocytochemistry.
Murine astrocytic and oligodendroglial cultures were kindly provided by M. Simons (MPI of Experimental Medicine, Göttingen, Germany). Cerebellar granule neurons were cultured from postnatal day 6 (P6) Wistar rat murine cerebella as described previously (Bilimoria and Bonni, 2008).
Granule neurons were either transfected 48 h after plating (2 d in vitro or DIV2) using the modified calcium-phosphate method with the indicated plasmids together with plasmids expressing GFP-FBXO41 or GFP-FBXO41 deletion mutants to visualize the transfected neurons (Konishi et al., 2004). To rule out that the morphological effects observed due to genetic manipulations were not a result of their effect on cell survival, the anti-apoptotic protein Bcl-XL was coexpressed in all experiments.
Survival assay.
For survival assay in neurons, rat granule neurons were transfected at DIV2 with the required plasmids together with β-gal plasmid, which served as a transfection marker. The neurons were fixed at DIV6 and subjected to immunocytochemistry using the β-gal and cleaved-caspase-3 antibodies. In addition, the nuclei were stained with the DNA dye bisbenzimide Hoechst 33258. Cleaved caspase 3 staining was observed in apoptotic neurons. A minimum of 100 transfected neurons per condition were counted and included in the analysis. The percentage of dead and living cells was calculated. Three independent experiments were included in the analysis and statistical analysis was performed using GraphPad Prism 5.0 using ANOVA.
In vivo electroporation.
In vivo electroporation was performed as described previously (Konishi et al., 2004; Stegmüller et al., 2006; Kannan et al., 2012a). In brief, plasmid DNA diluted in PBS (3–4 μl/animal) was injected into the P4 Wistar rat cerebellar cortex together with 0.03% Fast Green using a Hamilton syringe with a 30 gauge needle. U6/cmvGFP or FBXO41 RNAi#5-cmvGFP and/or myc-CMV, FBXO41, FBXO1-Res, FBXO41ΔCTR, or FBXO41-Res ΔCTR expression plasmids together with the synapsin(prom)-EGFP plasmid at a concentration of 8 μg/μl were injected together with 1 μg/μl Bcl-XL expression plasmid. After DNA injection, the animals were subjected to five short electric pulses (160–170 V for 50 ms with intervals of 950 ms). Five days later, the cerebella were isolated and sectioned (40 μm) using a Leica cryostat and subjected to immunohistochemistry with a GFP antibody (Santa Cruz Biotechnology). In all control U6-cmv-GFP cerebella, we observed a 90% association of GFP-positive granule neurons with parallel fibers: the parallel fiber index (Konishi et al., 2004; Stegmüller et al., 2006). GraphPad Prism was used to perform statistical analysis of neuronal migration and distribution data using two-way ANOVA (Bonferroni correction) test. Sections were imaged using the Leica SP5.
Generation of knock-out mice.
FBXO41 knock-out mice embryonic stem (ES) cells (C57BL/6-FBXO41tm1(KOMP)Vlcg) were generated by and purchased from the KOMP Repository at the University of California–Davis. Gene ablation was achieved by replacing the entire FBXO41 gene by a ZenUB1 reporter/selection (LacZ/neomycin) cassette, flanked by loxP sites, via homologous recombination. The FBXO41 knock-out ES cells were injected into a blastocyst from C57BL/6 mice and the blastocyst then implanted into the uterus of the foster mother. The resulting heterozygous animals were mated to generate FBXO41 wild-type, heterozygous, and homozygous mice. The mice were genotyped using the following primers:
Immunohistochemistry.
For LacZ staining, P30 adult heterozygous mice and wild-type littermates were subjected to transcardiac perfusion under deep anesthesia (ketamine/xylazine). After perfusion with PBS, pH 7.4, brains were fixed in situ with 4% (w/v) PFA in PBS. The brains were extracted from the cranium and postfixed in the same fixative for 3–4 h. After a brief rinse in PBS, brains were transferred to 30% sucrose in PBS for cryoprotection overnight. The brains were briefly washed and stored in PBS at 4°C. Vibratome sections of 30–50 μm were obtained with a Leica VT1000s Vibratome and collected in PBS. The free-floating sagittal brain sections were then incubated overnight at 37°C in the following solution: 2 mm MgCl2, 0.02% NP40, 0.01% sodium deoxycholate, 5 mm potassium ferrocyanide, 5 mm potassium ferricyanide, and 0.5 mg/ml X-gal in PBS. The sections were rinsed in PBS and mounted onto glass slides for imaging.
For paraffin sections, P12, P16, and P30 mice (FBXO41+/+ or FBXO41−/−) were subjected to transcardial perfusion with PBS followed by 4% PFA. The brains were extracted and postfixed in the same fixative overnight. After a brief rinse in PBS, the brains were either paraffin embedded and cut into 5 μm sagittal sections using a sliding microtome (Microm) or immersed in 30% sucrose for cryoprotection, embedded in OCT (Tissue Teck), and cut into 12-μm-thick sections using the Leica cryostat. The paraffin sections were stained with H&E or immunostained with antibodies against PCNA (Abcam), NeuN (Millipore), GFAP (Nova Castra), Iba1 (WAKO), and calbindin (Sigma-Aldrich) using the LSAB2 system (Dako). The TUNEL assay kit (Promega) was used to detect apoptotic neurons. DNase-digested tissue was used as positive control. Images were acquired using an Axiophot microsocope (Zeiss) and processed by ZEN software (Zeiss). For florescence staining on P16 FBXO41+/+ or FBXO41−/− cryosections, parvalbumin specific antibody was used and images were acquired using a Leica Sp5 confocal microscope.
The cellular density/distribution within the cerebellum was either counted manually or using a custom-designed ImageJ macro for DAB (GFAP) and H&E stainings, respectively. The sections were analyzed in a blinded manner with a least three sections per animal and three animals per genotype being included in the analysis. GraphPad Prism 5.0 was used to perform statistical analysis of cell migration and distribution data using paired t test and two-way ANOVA.
Mouse behavior.
The mice (P16: 5 males and 6 females, P30: 2 males and 2 females) were subjected to a previously established ataxia scoring protocol (Guyenet et al., 2010). To assess basic motor functions including balance and coordination, mice were subjected to four basic tests by a blinded investigator. The “clasping test” was used to assess whether the mice would clasp their forelimbs and hind limbs into their bodies or would spread their limbs when suspended by their tails (Lin et al., 2001). The ledge test, described previously (Garden et al., 2002), involved placing the P16 mouse on the 5-mm-wide and 30-cm-long ledge of a Plexiglas box and observing the response of the mouse. Although wild-type mice typically balanced themselves well and scurried along the bar of the cage, the knock-out mice with a neurological dysfunction typically froze in place or fell into the padded box. The animals were subjected to a gait analysis test as described previously (Guyenet et al., 2010) to evaluate coordination and muscle function. The mice were placed in a flat surface with their heads facing away from the investigator. The mice were scored on how well they supported their body weight and moved on four limbs. For the above tests, the mice were scored with a range of 0 to 3 (0 was for best performance and 3 for worst). All tests were repeated thrice for each animal and an average of the three trials was considered as the final score. The rotarod test, described previously (Radyushkin et al., 2009), was used to assess their balance and motor coordination. In brief, the rotarod is a rotating drum (Ugo Basile) at 12 rpm. The mice were placed individually on the rotarod and the latency of falling off was recorded using a stopwatch. The test period on the rotarod was 200 s.
Subcellular fractionation and centrosomal purification.
Tissue lysates of mice at different embryonic and postnatal stages, of granule neurons at various DIVs, and of cultured astrocytes and oligodendrocytes were subjected to SDS-PAGE and immunoblotting analyses as described previously (Stegmüller et al., 2006).
For subcellular fractionation, cultured cerebellar granule neurons at DIV8 were scraped into a detergent-free buffer A (10 mm HEPES, pH 7.9, 10 mm KCl, 0.1 mm EDTA, 0.1 mm EGTA, and protease inhibitors) and subjected to mechanical disruption using a 2 ml dounce homogenizer. While the nuclei were spun down at 500 g at 4°C, the supernatant was collected as the cytoplasmic fraction. Nuclei were washed once in 0.1% NP40-supplemented buffer A and then lysed in a buffer B (20 mm HEPES pH 7.9, 400 mm NaCl, 1 mm EDTA, 1 mm EGTA, and protease inhibitors) and pelleted at maximum speed (18,400 × g) at 4°C. The supernatant was collected as the nuclear fraction.
The centrosomal purification was performed as described previously (Vadhvani et al., 2013). Cultured granule neurons were exposed to cytochalasin D (1 μg/ml) and nocodazole (0.2 μm) for 1 h before lysis (1 mm HEPES, pH 7.2, 0.5% NP40, 0.5 mm MgCl2, and 0.1% β-mercaptoethanol supplemented with protease inhibitors 1 μg/ml pepstatin, 1 μg/ml aprotinin, 1 μg/ml leupeptin, and 1 mm PMSF). Cell lysates were then subjected to gradient centrifugation (60% sucrose, 10,000 × g, 30 min, 4°C). The resulting centrosomal fractions were purified by a discontinuous sucrose density gradient centrifugation (40%/50%/70% sucrose, 34,000 × g, 1 h, 4°C). Supernatant fractions were further subjected to immunoblotting analysis using the FBXO41 and γ-tubulin antibodies.
Results
FBXO41 is a neuron-specific F-box protein expressed in the CNS
To examine the role of FBXO41, we first generated and validated the affinity-purified antibody against FBXO41 (Fig. 1A). We then characterized the spatial and temporal expression of FBXO41 by immunoblotting murine tissue lysates obtained from various organs. We found FBXO41 to be expressed in CNS tissues including cortex, hippocampus, cerebellum, and spinal cord, but absent from the peripheral nervous system tissue such as sciatic nerve and from non-neural tissues (Fig. 1B,C). We also corroborated the CNS-specific expression of FBXO41 at the mRNA level with RT-PCR (Fig. 1D,E). Furthermore, we detected FBXO41 protein as early as embryonic day 10 (E10) in mouse (Fig. 1F) with abundant levels in postnatal stages in the cerebellum (Fig. 1G). Further immunoblotting analysis revealed that FBXO41 was expressed with increasing amounts in cerebellar granule neurons cultured for different DIV, but not in astrocytes or oligodendrocytes (Fig. 1H,I), thus confirming the neuron-specific expression. Last, on performing subcellular fractionation analyses of cultured granule neurons, we found that endogenous FBXO41 was localized in the cytoplasm and excluded from the nucleus (Fig. 1J).
Because our purified FBXO41 antibody failed to work in immunocytochemistry, we resorted to an overexpression analysis of GFP-tagged FBXO41 to support its cytoplasmic localization in neurons (Fig. 1K). In addition, we discovered a conspicuous dot-like accumulation of FBXO41 near the nucleus, which we later confirmed to be the centrosome because GFP-FBXO41 colocalized with the centrosomal marker pericentrin 2 (Fig. 1L). Consistent with these results, we found that endogenous FBXO41 also cosegregated with the centrosome-associated protein γ-tubulin in the bottom fractions of centrosome purification experiments using cultured granule neurons (Fig. 1M). These experiments identify FBXO41 as a neuron-specific protein in the CNS, which localizes to the centrosome and cytoplasm.
Cytoplasmic localization of FBXO41 is important for neuronal migration in the cerebellum
Having found that FBXO41 localized to different cellular regions, we generated GFP-tagged FBXO41 deletion mutants to identify the region that would target FBXO41 to the centrosome (Fig. 2A, B). Upon expression in HEK293T cells and in neurons, we identified a sequence that was required to direct FBXO41 to the centrosome (Fig. 2A,B); we refer to it as centrosomal targeting region (CTR, aa 179–354) hereafter. In contrast to wild-type FBXO41, FBXO41 ΔCTR failed to localize to the centrosome and dispersed in the cytoplasm in both HEK293T cells and granule neurons (Fig. 2A). Together, these experiments established the dual localization of FBXO41 at the centrosome and cytoplasm.
The centrosome and in particular centrosome-associated proteins have been the focus of many studies elucidating mechanisms of neuronal migration (Wynshaw-Boris and Gambello, 2001; Tsai and Gleeson, 2005; Higginbotham and Gleeson, 2007). Therefore, the centrosomal localization of FBXO41 prompted us to determine whether FBXO41 plays a role in neuronal migration using the in vivo electroporation technique (Konishi et al., 2004; Holubowska et al., 2014). We started out with a loss-of-function approach for which we generated several FBXO41 hairpin constructs and validated the efficient downregulation of exogenous FBXO41 in HEK293T cells and endogenous FBXO41 in granule neurons by the FBXO41 RNAi#5 plasmid (Fig. 2C,D). To establish the specificity of knock-down-induced phenotypes, we generated and validated an RNAi-resistant FBXO41-Rescue (Res) plasmid harboring four silent mutations in the targeting region (Fig. 2E).
We then injected the bicistronic FBXO41 RNAi#5-cmvGFP plasmid or control vector into the cerebella of P4 Wistar rat pups and subjected them to electrical pulses, followed by analyses of coronal sections at P9. Compared with control developing cerebella, in which neuronal precursors undergo radial migration from the external granule layer (EGL) to the internal granular layer (IGL) (Altman and Bayer, 1997), we found that significantly more FBXO41 knock-down neurons were stalled in the EGL/ML (Fig. 2F). We quantified the number of control-electroporated and FBXO41 RNAi neurons in four cerebellar regions (EGL/ML, inner, middle, and outer IGL) and found significantly more FBXO41 RNAi neurons in the EGL/ML (Fig. 2G). The remaining FBXO41 RNAi neurons were most abundant in the outer IGL, whereas significantly fewer FBXO41 RNAi neurons migrated into the middle and inner IGL, indicating a slower migration speed (Fig. 2G). These data suggest that FBXO41 promotes neuronal migration.
Next, we investigated whether the centrosomal or the cytoplasmic localization of FBXO41 is important for neuronal migration. We injected FBXO41 RNAi plasmid alone or together with the RNAi-resistant FBXO41-Res or FBXO41-Res ΔCTR plasmid or appropriate control vectors into the cerebella of P4 Wistar rat pups and subjected them to electrical pulses. Five days later, we analyzed electroporated cerebellar granule neurons in coronal sections. We found that, unlike FBXO41 RNAi neurons, the control neurons, FBXO41-Res neurons, and FBXO41-Res ΔCTR neurons managed to migrate efficiently away from the EGL/ML region (Fig. 2H). In the outer IGL, control neurons were indistinguishable from FBXO41-Res ΔCTR neurons, but significantly less numerous than FBXO41 RNAi or FBXO41-Res neurons (Fig. 2I). In the middle section of the IGL, we found expectedly less FBXO41 RNAi neurons, but an equal number of FBXO41-Res neurons and less FBXO41-Res ΔCTR neurons (Fig. 2I). In the inner IGL, both FBXO41 RNAi and FBXO41-Res neurons are significantly less numerous than control neurons (Fig. 2I). FBXO41-Res ΔCTR neurons, however, migrated equally efficient compared with control neurons. In addition, to underscore these findings, we examined FBXO41 gain-of-function in vivo. We electroporated P4 cerebella with control vector, the wild-type FBXO41, or FBXO41 ΔCTR expression plasmid and analyzed coronal sections from P9 pups (Fig. 2J). Quantification of the granule neurons that migrated into subdivided sections of the IGL demonstrated that control neurons are more numerous in the outer IGL and equally numerous in the middle IGL compared with wild-type FBXO41 and FBXO41 ΔCTR neurons (Fig. 2K). FBXO41 neurons migrated more efficiently into the inner IGL than control neurons and FBXO41 ΔCTR neurons were significantly more numerous in the inner IGL (Fig. 2K). Collectively, these data indicate that the FBXO41 RNAi-induced phenotype is specific to FBXO41 and suggest that cytoplasmic FBXO41 is crucial to stimulate the migration of cerebellar granule neurons.
FBXO41−/− mice display an ataxia-like phenotype and defects in cerebellar development
Having identified a role for FBXO41 in neuronal migration, we decided to take a mouse genetics approach to explore the effects of the loss of FBXO41 on neuronal migration. Therefore, we generated an FBXO41 knock-out (KO; C57BL/6-FBXO41tm1(KOMP)Vlcg) mouse in which the FBXO41 gene was replaced by a LacZ reporter cassette (for cloning strategy, see www.KOMP.org). After genotyping PCR to identify the integrated LacZ cassette (Fig. 3A), we performed immunoblotting analysis and determined the successful deletion of FBXO41 in the FBXO41−/− mice and observed approximately half the dosage in FBXO41+/− mice (Fig. 3B).
We started out by examining the FBXO41−/− mice and observed a slight developmental delay already at P5, which became even more evident thereafter. Approximately 80% of homozygous mice died before P14 (Fig. 3C); the few surviving homozygous mice had a variable lifespan but never longer than 10 weeks. This compelled us to describe the strong phenotype displayed by FBXO41−/− mice at P16 (Fig. 3D). The most obvious characteristics of the P16 FBXO41−/− mice were severely reduced body and brain weight compared with their FBXO41+/− and FBXO41+/+ littermates (Fig. 3E,F).
In addition to reduced body size, FBXO41−/− mice exhibited motor deficits characterized by a severely ataxic gait. To quantify this aspect of the phenotype, we subjected FBXO41+/+, FBXO41+/−, and FBXO41−/− mice at P16 to an ataxia scoring protocol described previously by Guyenet et al. (2010), with 0 representing normalcy and 3 representing the strongest manifestation of the phenotype. We observed that FBXO41−/− mice displayed an abnormal gait characterized by dragging of the hind limbs, impaired balance, and tremors (Fig. 3G). We also tested the balance of FBXO41−/− mice along with their littermates using the ledge test (Fig. 3H) and their motor coordination on the rotarod test (Fig. 3I). We found that FBXO41−/− mice performed significantly worse than their littermates in all tested paradigms. FBXO41−/− mice also adopted a hindlimb clasping posture when suspended by the tail (Fig. 3J,K). The heterozygous FBXO41 mice were indistinguishable from wild-type littermates in all tests. These observations suggest that loss of FBXO41 in mice results in ataxia-like motor defects as a result of neurological deficits.
Abundant neuronal expression of FBXO41 in the brain
We next took advantage of the LacZ cassette driven by the FBXO41 promoter in the aforementioned mice to characterize the spatial expression of FBXO41 in the CNS by subjecting sagittal sections from P30 FBXO41+/− mice to LacZ staining. We observed a wide distribution of β-Galactosidase (β-Gal) throughout the brain (Fig. 4A), with abundant FBXO41 expression, for example, in various layers of the hippocampus and the cortex (Fig. 4B). We also detected a weaker expression in the spinal cord (Fig. 4C). In the cerebellum, FBXO41 was expressed in the granule cell layer and deep cerebellar nuclei, but was absent from Purkinje cells, interneurons of the molecular layer, and white matter (Fig. 4D). We excluded nonspecific signals by subjecting a brain section from an FBXO41+/+ littermate to LacZ staining together with the FBXO41−/− sections (Fig. 4E).
No signs of apoptosis or inflammation in the young FBXO41−/− mouse
Before investigating the potential role of FBXO41 in neuronal migration, we sought to establish whether FBXO41 had any effect on the overall integrity of the cells in the cerebellum as the in vivo electroporation experiments were performed in the presence of neuronal survival-promoting protein Bcl-XL. Therefore, we could not exclude a prosurvival function of FBXO41 in neurons and possible early effects on neuronal health. Compromised neuronal survival has been shown, for example, in the cerebellum of equally young repair-deficient Cockayne syndrome mice (Laposa et al., 2007). Therefore, we investigated whether the deletion of the FBXO41 gene would trigger any histopathological changes including neurodegeneration or inflammation in the young cerebellum. We examined the P16 cerebellum when neuronal migration has subsided and the cerebellar region that consists of precursor cells and postmitotic neurons (EGL) ceases to exist. We subjected sagittal paraffin sections from FBXO41+/+ and FBXO41−/− brains to immunohistochemistry. Using TUNEL staining to mark apoptotic cells, we could not find any increase in cell death in the cortex, hippocampus, or cerebellum at P16 (Fig. 5A–D). We also did not detect any activation of microglia in the P16 brain (Fig. 5E–H) or changes in astrogliosis (Fig. 5I,J). These results suggest that loss of FBXO41 does not trigger any degenerative changes in the adolescent brain at P16.
Because we could not detect any degenerative events in the P16 FBXO41−/− brain, we explored whether loss of FBXO41 has any effects on the gross morphology of the brain possibly due to its role in migration. We thus analyzed H&E sections from P16 and included P12 and P30 in our analyses. The brain sizes of the FBXO41−/− mice were consistently smaller than the wild-type brains (Fig. 6A–C). Remarkably, we noticed that the P30 FBXO41−/− cerebellum adopted a distorted architecture with an unsual intralobular outfolding between lobules V and VI (Fig. 6C). We also quantified the area taken up by the cortex, hippocampus, and cerebellum with respect to the area of the entire brain. We found that, by P30, cortices and hippocampi from wild-type and homozygous FBXO41 mice occupied a comparable relative area (Fig. 6D,E). The cerebellum, however, occupied a significantly smaller area (Fig. 6F). These results indicate that the cerebellum displays the most obvious morphological defects of the FBXO41−/− brain at the ages analyzed.
Loss of FBXO41 delays neuronal migration in the cerebellum
Due to the abnormal architecture of the P30 cerebellum in the FBXO41−/− mice and our findings that FBXO41 regulates neuronal migration, we decided to first examine the P16 cerebellum when neuronal migration events and thus lamination are completed. We observed abnormal cerebellar lamination in FBXO41−/− mice, which displayed a residual EGL and migrating cells of elongated shape in the ML (Fig. 7A). This was not the case in FBXO41+/+ cerebella (Fig. 7A). Quantification of this phenotype revealed a significant increase in the number of cells in the ML and residual EGL (Fig. 7B–D). We then monitored the development of the cerebellum of the KO mice before and after the completion of lamination. As a consequence of the delayed migration phenotype, we anticipated a thicker EGL in the younger cerebellum. This was indeed the case when we analyzed the P12 cerebella (Fig. 7E), where the EGL of FBXO41−/− cerebella took up a larger area relative to the total cerebellum (Fig. 7F), and we also found more cells in the ML (Fig. 7G). At P30, although there was no longer an EGL in the FBXO41−/− cerebella (Fig. 7H), the analysis of the ML still revealed a significantly larger number of cells in the knock-out ML compared with the wild-type condition (Fig. 7I,J). These findings indicate that, although the migrating cells eventually catch up and reach the IGL, FBXO41 is required to maintain a normal migration speed in the cerebellum.
To characterize the nature of the supernumerous cells of the EGL and ML in more detail, we subjected sagittal paraffin sections form P12, P16, and P30 cerebella from wild-type and homozygous littermates to immunohistochemistry using NeuN, parvalbumin (PV), and PCNA antibodies to identify granule neurons, Purkinje cells, and mitotic precursors, respectively. While NeuN and PCNA gives insight into the composition of the EGL, PV shows the proper arrangement of Purkinje cells. NeuN staining revealed that the molecular layer of the FBXO41−/− cerebellum harbored at all analyzed ages significantly more NeuN+ cells compared with wild-type littermates (Fig. 8A,B). Interestingly, not all cells of the residual EGL of the P16 FBXO41−/− cerebellum were NeuN+. Interestingly, although at P12, PCNA+ cells were present in the outer EGL of both FBXO41+/+ and FBXO41−/− cerebella, we found mitotic PCNA+ cells in the residual EGL of the P16 FBXO41−/− cerebellum (Fig. 8C,D). At P30, there were no PCNA+ cells in the EGL or ML of either genotype. With the parvalbumin staining as a marker for Purkinje cells, we observed properly arranged Purkinje cells and the expansion of their dendrites into the ML of wild-type cerebella and all the way up to the residual EGL cells in the P16 FBXO41−/− cerebellum (Fig. 8E). In summary, our analyses indicate that the overall composition of the EGL is unaltered because it harbors both mitotic cells and postmitotic neurons. Our results also indicate that the more slowly subsiding EGL of the FBXO41−/− cerebellum still consists of granule neurons and mitotic precursor cells. Last, our analyses identify the supernumerous cells in the molecular layer as migrating granule neurons.
In a final experiment, we addressed whether the delay in neuronal migration, and likely impairment of cerebellar wiring, affected not only the gross morphology, but also the integrity of the neurons in the cerebellum of the P30 FBXO41−/− mice. Although these mice gained weight, they were always significantly lighter than wild-type littermates (Fig. 9A) and were still motor impaired and unable to reach for the food tray and water bottle in the cage and thus required special supply of food and water. Analyses showed that the mice displayed an ataxic gait, had strong hindlimb clasping, and performed poorly on the ledge test (Fig. 9B–D). We also subjected FBXO41+/+ and FBXO41−/− brain sections to TUNEL staining and found little or no increase of apoptotic cells in the cortex but a significant increase in the hippocampus and the cerebellum (Fig. 9E–H). In the latter region, many of the apoptotic cells appeared clustered in the intralobular outfolding and collapsed lobule VI (Fig. 9E). These results suggest that the delay of cerebellar development as a result of loss of FBXO41 not only triggers changes in the morphology, but also affects the integrity of neurons.
To support the role of FBXO41 in apoptosis, we performed cell survival assays using the cerebellar granule neuron culture system. We examined control-transfected and FBXO41 RNAi neurons and found that knock-down of FBXO41 using a functional RNAi #5, but not the nonfunctional RNAi#8, leads to an increase in cleaved caspase 3+ neurons (Fig. 9I, J). To ensure the specificity of FBXO41 RNAi-induced cell death, we performed a rescue experiment and expressed the RNAi-resistant FBXO41 (FBXO41-Res) in the background of FBXO41 RNAi (Fig. 9K). We found that the number of apoptotic neurons in the rescue condition was reduced to control level. These results support a prosurvival role for FBXO41 in neurons.
Discussion
In this study, we have characterized the novel neuron-specific F-box protein FBXO41 in the establishment and maintenance of proper cerebellar architecture. FBXO41 belongs to the large family of F-box proteins that share the F-box domain. As a member of this family, FBXO41 is anticipated to be a subunit of an E3 ubiquitin ligase, which will be discussed in the follow-up paper (Mukherjee M., Holubowska A., Schwedhelm-Domeyer N., Gellerer A., Kannan M., Stegmüller J., unpublished data). FBXO41 has a striking neuron-specific expression in various areas of the CNS. At the subcellular level, FBXO41 localizes to the cytoplasm and the centrosome. In vivo electroporation experiments in the cerebellum revealed cytoplasmic FBXO41 as the crucial player. Further work will be necessary to identify mechanisms underlying FBXO41-mediated neuronal migration. Successful neuronal migration of the cerebellum is dependent on proper guidance by extrinsic cues, on cell-intrinsic mechanisms including cytoskeletal dynamics or transcription factors, and on the interplay of both (Solecki et al., 2006; Tiveron and Cremer, 2008; Romaniello et al., 2015). Because of FBXO41's abundant cytoplasmic expression in neurons, it could, for example, interfere intrinsically with the dynamics of the leading edge or intercept incoming extrinsic promigratory stimuli.
Upon systemic deletion of the FBXO41 gene in the mouse, we observed the most severe morphological changes in the cerebellum, characterized by the failure of migrating granule neurons to reach the IGL within a developmentally appropriate time window. A comparable delay in migration of granule neurons in the cerebellum has been described, for example, in mouse models lacking the actin-binding protein profilin1 or the microtubule-binding protein APC2 (Adenomatous Poliposis Coli 2; Kullmann et al., 2012; Shintani et al., 2012). Because we found obvious and persisting ataxia-like motor deficits in the cerebellum in the FBXO41−/− mouse, it is very likely that the major motor phenotype can be attributed to this phenotype. Cerebellar dysfunction has also been characterized in mice modeling human cerebellar ataxias, in which the development of the cerebellum has derailed. Deletion of the Ahi1 gene in mice for example results in abnormal cerebellar development and is thus viewed as a Joubert syndrome mouse model (Lancaster et al., 2011). In addition, conditional deletion of the Robo3 gene in the cerebellum, mutations of which are associated with horizontal gaze palsy with progressive scoliosis, recapitulate developmental deficits in the cerebellum that lead to severely ataxic mice (Renier et al., 2010; Badura et al., 2013).
Ataxia is often associated with degenerative events in the cerebellum (Zoghbi, 2000; Orr and Zoghbi, 2007; Klockgether and Paulson, 2011). Although we did not find any signs of apoptosis or inflammation at a very young age, we did observe apoptotic events in the young adult mice. This indicates that loss of FBXO41 triggers defects in neuronal migration in the developing cerebellum, which may contribute largely to the motor deficits in the young mouse. The onset of neurodegeneration in the young adult mouse could be a consequence of deferred wiring and faulty architecture in the cerebellum or the requirement of FBXO41 for long-term integrity and health of the neurons. Although migrating neurons of the cerebellum catch up in the older FBXO41−/− mouse and the animals gain weight, the impending neurodegeneration is likely also to contribute to the small-sized cerebellum and the persisting motor symptoms. Neurodegeneration in the cerebellum leading to motor dysfunction is causative in several human cerebellar disorders such as spinocerebellar ataxias (SCA), which have been successfully modeled (Grote and La Spada, 2003; Colomer Gould, 2012; Cendelin, 2014). Among these, the SCA7 mouse also displays early onset of ataxia and premature death (Yoo et al., 2003). Although other deficits contribute to the severity of the phenotype of this mouse, the ataxic phenotype can be ascribed to cerebellar degeneration.
We also find that FBXO41 is abundantly expressed in, for example, the cortex and the hippocampus. Therefore, it is conceivable that FBXO41 affects neuronal migration in these regions during development as well. The early postnatal cortex, however, does not appear to have obvious histopathological disturbances (unpublished data). This could mean that FBXO41 has only a migration-regulating role in the cerebellum or that migration deficits in the cortex have caught up in the course of development. A thorough examination of the lamination of the embryonic cortex is thus required to monitor the migration progress. The same holds true for other FBXO41-positive neurons that require migration to reach their final destination, including hippocampal neurons. FBXO41 is also expressed in adult cerebellar granule neurons when developmental events are completed. Given the high expression of FBXO41, not only in the adult cerebellum, but also several other areas of the brain including the hippocampus, a role in the development and maintenance of synapses is also possible and deserves further investigation.
Developmental delay of the cerebellum and cerebellar and hippocampal neurodegeneration upon loss of FBXO41 could also affect cognitive function. Although the hippocampus is famously associated with learning and memory, recent work has revealed that the cerebellum plays a significant role in cognition. Developmental deficiencies of the cerebellum have been linked to psychiatric disorders including autism spectrum disorders (Schmahmann and Sherman, 1998; Schmahmann et al., 2007; Fatemi et al., 2012; Basson and Wingate, 2013), so cognitive deficits may coexist along with motor impairment in the FBXO41−/− mice.
The ataxia-like phenotype of the knock-out mice supports the notion that FBXO41 is an important player in motor coordination and the FBXO41−/− mouse can thus be viewed as a novel model for congenital ataxia. Because ∼40% of ataxias are of unknown genetic causes (Sailer and Houlden, 2012), the search for causative genes is imperative and the discovery of new genes such as the FBXO41 gene and the recently identified TRCP3 gene as critical factors of cerebellar development and integrity are important because mutations and deletions in the these genes might be associated with unresolved forms of congenital ataxias (Becker et al., 2009; Becker, 2015). In addition, future elucidation of the FBXO41 pathway will shed more light onto the mechanisms that regulate cerebellar development and will contribute to our understanding of the role of FBXO41 in proper motor coordination and possibly disease.
Footnotes
The study was funded by the Max Planck Society, the Cluster of Excellence, the Deutsche Forschungsgemeinschaft Research Center for Nanoscale Microscopy and Molecular Physiology of the Brain, and the Junior Group Stipend of the University of Göttingen. We thank D. Brockelt, S. Vingill, and A. Matz for critical reading of the manuscript; U. Bode and M. Schindler for ES cell culture and ES cell injection, respectively; R. Bunse for help in the initial phase of the study; A. Gellerer for help in the later phase of the study; and S. Papiol for help with statistical analyses.
The authors declare no competing financial interests.
- Correspondence should be addressed to Judith Stegmüller, MPI of Experimental Medicine, Hermann Rein Strasse 3, 37075 Göttingen, Germany. stegmueller{at}em.mpg.de