Thomas Schmitt-John

Mutation of Vps54 causes motor neuron disease and defective spermiogenesis in the wobbler mouse

Vacuolar-vesicular protein sorting (Vps) factors are involved in vesicular trafficking in eukaryotic cells. We identified the missense mutation L967Q in Vps54 in the wobbler mouse, an animal model of amyotrophic lateral sclerosis, and also characterized a lethal allele, Vps54β-geo. Motoneuron survival and spermiogenesis are severely compromised in the wobbler mouse, indicating that Vps54 has an essential role in these processes.

Spatiotemporal progression of neurodegeneration and glia activation in the wobbler neuropathy of the mouse

The wobbler mouse (phenotype WR; genotype wr/wr) has been investigated as a model for neurodegenerative diseases like SMA and ALS. A new diagnostic marker based on a polymorphism in the closely linked chaperonine gene Cct4 enabled us to diagnose the allelic status at the wr locus within the original background strain C57BL/6. Using this marker, we investigated the spatiotemporal progression of neuropathology in WR mice from postnatal day (d.p.n.) 10 to 60. Neurodegeneration starts at 13 d.p.n. in the thalamus (N. ventralis), in deep cerebellar nuclei, brain stem (N. vestibularis) and spinal cord interneurons. The motor nuclei of spinal nerves and motoneurons degenerate from 15 d.p.n. onward. Reactive astrocytes are observed around 17 d.p.n. in the white and grey matter of the spinal cord. Microgliosis occurs only from 23 d.p.n. onward. Our data demonstrate that in the WR disease, neurodegeneration in thalamus, cerebellum, and brain stem precedes motoneuron degeneration, astrogliosis and microgliosis.

Reduced GABAergic Inhibition Explains Cortical Hyperexcitability in the Wobbler Mouse Model of ALS

Amyotrophic lateral sclerosis (ALS) is a progressive degenerative disease of the central nervous system. Symptomatic and presymptomatic ALS patients demonstrate cortical hyperexcitability, which raises the possibility that alterations in inhibitory gamma-aminobutyric acid (GABA)ergic system could underlie this dysfunction. Here, we studied the GABAergic system in cortex using patch-clamp recordings in the wobbler mouse, a model of ALS. In layer 5 pyramidal neurons of motor cortex, the frequency of GABA(A) receptor-mediated spontaneous inhibitory postsynaptic currents was reduced by 72% in wobbler mice. Also, miniature inhibitory postsynaptic currents recorded under blockade of action potentials were decreased by 64%. Tonic inhibition mediated by extrasynaptic GABA(A) receptors was reduced by 87%. In agreement, we found a decreased density of parvalbumin- and somatostatin-positive inhibitory interneurons and reduced vesicular GABA transporter immunoreactivity in the neuropil. Finally, we observed an increased input resistance and excitability of wobbler excitatory neurons, which could be explained by lack of GABA(A) receptor-mediated influences. In conclusion, we demonstrate decreases in GABAergic inhibition, which might explain the cortical hyperexcitability in wobbler mice.

Endosomal accumulation of APP in wobbler motor neurons reflects impaired vesicle trafficking: Implications for human motor neuron disease

BackgroundThe cause of sporadic amyotrophic lateral sclerosis (ALS) is largely unknown but hypotheses about disease mechanisms include oxidative stress, defective axonal transport, mitochondrial dysfunction and disrupted RNA processing. Whereas familial ALS is well represented by transgenic mutant SOD1 mouse models, the mouse mutant wobbler (WR) develops progressive motor neuron degeneration due to a point mutation in the Vps54 gene, and provides an animal model for sporadic ALS. VPS54 protein as a component of a protein complex is involved in vesicular Golgi trafficking; impaired vesicle trafficking might also be mechanistic in the pathogenesis of human ALS.ResultsIn motor neurons of homozygous symptomatic WR mice, a massive number of endosomal vesicles significantly enlarged (up to 3 μm in diameter) were subjected to ultrastructural analysis and immunohistochemistry for the endosome-specific small GTPase protein Rab7 and for amyloid precursor protein (APP). Enlarged vesicles were neither detected in heterozygous WR nor in transgenic SOD1(G93A) mice; in WR motor neurons, numerous APP/Rab7-positive vesicles were observed which were mostly LC3-negative, suggesting they are not autophagosomes.ConclusionsWe conclude that endosomal APP/Rab7 staining reflects impaired vesicle trafficking in WR mouse motor neurons. Based on these findings human ALS tissues were analysed for APP in enlarged vesicles and were detected in spinal cord motor neurons in six out of fourteen sporadic ALS cases. These enlarged vesicles were not detected in any of the familial ALS cases. Thus our study provides the first evidence for wobbler-like aetiologies in human ALS and suggests that the genes encoding proteins involved in vesicle trafficking should be screened for pathogenic mutations.

Assignment1 of homologous genes, Peli1/PELI1 and Peli2/PELI2, for the pelle adaptor protein Pellino to mouse chromosomes 11 and 14 and human chromosomes 2p13.3 and 14q21, respectively, by physical and radiation hybrid mapping

Pellino has been identified as a dimerization partner of the Drosophila protein Pelle, a Ser-Thr kinase that is involved in the Toll receptor signaling pathway (Grosshans et al., 1999). The signal transmitted by Toll receptor and Pelle kinase acts on the Dorsal/Cactus complex and determines the dorsoventral axis of the Drosophila embryo, as inferred from the phenotypes caused by mutations in the respective genes, as well as pathogen resistance in the adult (Karin and Hunter, 1995). However, no mutations are known in the Pellino gene. Three mammalian orthologs of Pelle (IRAK-1, Cao et al., 1996; IRAK-2, Muzio et al., 1997; IRAK-M, Wesche et al., 1999) have been identified and several Toll-like receptors (TLR) are known in humans, which are associated with innate immune response (Medzhitov et al., 1997). So far Pellino homologues have been identified in Caenorhabditis elegans (Rich et al., 2000) and the urochordate Ciona intestinalis, in which expression was found in the notochord (Hotta et al., 2000). In the course of the positional cloning of the neurological mutation wobbler of the mouse (Resch et al., 1998) we found an EST homologous to the Drosophila gene coding for Pellino. We therefore isolated cDNAs and characterized the genes of Pellino homologues in man and mouse. Materials and methods

Reduced fertilization after ICSI and abnormal phospholipase C zeta presence in spermatozoa from the wobbler mouse

Failed fertilization after intracytoplasmic sperm injection (ICSI) can be due to a reduced oocyte-activation capacity caused by reduced concentrations and abnormal localization of the oocyte-activation factor phospholipase C (PLC) zeta. Patients with this condition can be helped to conceive by artificial activation of oocytes after ICSI with calcium ionophore (assisted oocyte activation; AOA). However some concern still exists about this approach. Mouse models could help to identify potential oocyte-activation strategies and evaluate their safety. In this study, the fertilizing capacity of wobbler sperm cells was tested and the efficiency of AOA with two exposures to ionomycin to restore fertilization and embryo development was studied. The quality of the obtained blastocysts was assessed and embryo transfer was performed to evaluate post-implantation development. The presence of PLCzeta in the spermatozoa and testis of the wobbler mouse was evaluated by PLCzeta immunostaining and quantitative reverse-transcription polymerase chain reaction. Sperm cells from wobbler mice had reduced fertilizing capacity and abnormalities in PLCzeta localization, but not in its expression. Artificially activating the oocytes restored fertilization and embryo development. Therefore, the wobbler mouse can be a model for failed fertilization after ICSI to study PLCzeta dynamics and aid in optimization of the AOA method.

Homology between human chromosome 2p13.3 and the wobbler critical region on mouse chromosome 11: comparative high-resolution mapping of STS and EST loci on YAC/BAC contigs

Abstract. Human Chr 2p13-14 and homologous regions on mouse Chrs 6 and 11 have been subjects of previous studies because they comprise the loci for several neuromuscular diseases. Here we report on high-resolution mapping of 55 STS and EST loci on human Chr 2p13.3 and of 47 markers on the corresponding region on proximal mouse Chr. 11. The maps comprise several known genes, MEIS1/Meis1, RAB1a/Rab1a, MDH1/Mor2, OTX1/Otx1, and REL on human 2p13.3 and mouse Chr 11, respectively, as well as the wobbler (wr) critical region of the mouse. Whereas a perfect correspondence was found in most of the 4-Mb region, a small rearrangement was discovered around the OTX1/Otx1 locus. The detailed STS and EST transcript maps of these regions and a further narrowing down of the mouse wr critical region to the interval between D11Mit79 and D11Mit19 allow for the selection of positional candidate genes for wr, and the exclusion of others.

Loss of Vps54 Function Leads to Vesicle Traffic Impairment, Protein Mis-Sorting and Embryonic Lethality

The identification of the mutation causing the phenotype of the amyotrophic lateral sclerosis (ALS) model mouse, wobbler, has linked motor neuron degeneration with retrograde vesicle traffic. The wobbler mutation affects protein stability of Vps54, a ubiquitously expressed vesicle-tethering factor and leads to partial loss of Vps54 function. Moreover, the Vps54 null mutation causes embryonic lethality, which is associated with extensive membrane blebbing in the neural tube and is most likely a consequence of impaired vesicle transport. Investigation of cells derived from wobbler and Vps54 null mutant embryos demonstrates impaired retrograde transport of the Cholera-toxin B subunit to the trans-Golgi network and mis-sorting of mannose-6-phosphate receptors and cargo proteins dependent on retrograde vesicle transport. Endocytosis assays demonstrate no difference between wobbler and wild type cells, indicating that the retrograde vesicle traffic to the trans-Golgi network, but not endocytosis, is affected in Vps54 mutant cells. The results obtained on wobbler cells were extended to test the use of cultured skin fibroblasts from human ALS patients to investigate the retrograde vesicle traffic. Analysis of skin fibroblasts of ALS patients will support the investigation of the critical role of the retrograde vesicle transport in ALS pathogenesis and might yield a diagnostic prospect.

Pathoproteomics of testicular tissue deficient in the GARP component VPS54: The wobbler mouse model of globozoospermia

In human globozoospermia, round‐headed spermatozoa lack an acrosome and therefore cannot properly interact with oocytes. In the wobbler (WR) mouse, an L967Q missense mutation in the vesicular protein‐sorting factor VPS54 causes motor neuron degeneration and globozoospermia. Although electron microscopy of WR testis shows all major components of spermatogenesis, they appear in a deranged morphology that prevents the formation of the acrosome. In order to determine proteome‐wide changes, affected testes were analysed by 2D‐DIGE and MS. The concentration of 8 proteins was increased and that of 35 proteins decreased as compared to wild type. Mass spectrometric analysis identified proteins with an altered concentration to be associated with metabolite transport, fatty acid metabolism, cellular interactions, microtubule assembly and stress response (chaperones Hsp70–2 and Hsp90α). Minor changes were observed for proteins involved in cell redox homeostasis, cytoskeleton formation, PTMs, detoxification and metabolism. The most dramatically decreased protein in WR testis was identified as fatty acid binding protein FABP3, as confirmed by immunoblot analysis. We conclude that a missense mutation in VPS54, an essential component of the Golgi‐associated retrograde protein complex, not only prevents the formation of an acrosome but also initiates a cascade of metabolic abnormalities and a stress reaction.

Comparison of pre- and post-implantation development following the application of three artificial activating stimuli in a mouse model with round-headed sperm cells deficient for oocyte activation

STUDY QUESTION Does the application of three different artificial activating stimuli lead to a difference in pre- and post-implantation embryo development in the wobbler mouse, a mouse model with oocyte activation deficient round-headed sperm cells similar to human globozoospermia? SUMMARY ANSWER No gross differences were found between strontium chloride, electrical pulses or ionomycin with respect to the pre- and post-implantation development in the wobbler mouse. WHAT IS KNOWN ALREADY Fertilization failure following intra-cytoplasmic sperm injection (ICSI) occurs in 1-3% of the ICSI cycles in human assisted reproduction technology (ART) and has been successfully overcome by different artificial activating stimuli. No comparison has been made yet in terms of their efficiency and safety. STUDY DESIGN, SIZE, DURATION Calcium release and embryo development were compared between oocytes fertilized by wobbler and wild-type (WT) sperm following ICSI with or without three different artificial activating agents. Preimplantation development was assessed on 70 injected oocytes on average per group. On average, 10 foster mothers were used per activating group to compare post-implantation development. PARTICIPANTS/MATERIALS, SETTING, METHODS We used the wobbler mouse model that possesses oocyte activation deficient round-headed sperm cells. First, the calcium release following ICSI using wobbler sperm was compared with that of WT sperm. Outcome measures were the percentage of oocytes that showed calcium release and their mean amount of calcium rises. Secondly, the pre- and post-implantation development was assessed following ICSI with wobbler sperm plus artificial oocyte activation using either: (i) strontium chloride (Wob-Sr), (ii) electrical pulses (Wob-E) or (iii) ionomycin (Wob-I). Outcome measures were the activation, cleavage and blastocyst rates and the assessment of blastocyst quality by differential staining. Following mouse embryo transfer, pregnancy and birth rates as well as mean litter sizes were examined. Finally, pups were followed up until 8 weeks of age and then mated with fertile controls to assess their fertility. MAIN RESULTS AND THE ROLE OF CHANCE The percentage of oocytes showing calcium rises as well as the number of calcium rises per oscillating oocyte were significantly lower in the wobbler group when compared with the WT group (9.3 versus 96% and 2.1 calcium rises versus 31 calcium rises) (P < 0.001). The fertilization rate was significantly lower in the wobbler group (11.4%) when compared with the WT group (92.1%) and the artificial activation groups (strontium chloride: 99%, electrical pulses: 99% and ionomycin: 81%, respectively) (P < 0.001). Post-implantation development did not differ significantly between the WT and artificial activation groups, with pregnancy rates in favor of strontium chloride and electrical pulses. The weight of the male pups did not differ between the study groups, whereas the weight of the female pups originating from Wob-Sr embryos was significantly lower at weeks 2, 3 and 4 when compared with female pups originating from WT embryos. However, the latter difference was not observed at later time points, nor in the other artificial activating groups. All offspring mated successfully with fertile controls. LIMITATIONS, REASONS FOR CAUTION Results in animal models should be extrapolated with caution to a subfertile human population. Also, ionomycin is currently the most widely used artificial oocyte activating agent in human ART. WIDER IMPLICATIONS OF THE FINDINGS The low frequency of observed calcium rises and the low activation rate make the wobbler mouse a highly suitable model to study oocyte activation deficiency. Strontium chloride and electrical pulses were more efficient means to restore fertilization rates and to support pre- and post-implantation embryonic development than ionomycin. STUDY FUNDING/COMPETING INTEREST(S) This work was supported by the Flemish foundation of Scientific Research (FWO-Vlaanderen) (aspirant clinical research mandate to F.V.M., fundamental clinical research mandate to P.D.S.); and Ghent University grant (KAN-BOF E/01321/01 to B.H.). The authors have no competing interests to declare.