SummaryWe have established a procedure for isolating native peroxisomal membrane protein complexes from cultured human cells. Protein-A-tagged peroxin 14 (PEX14), a central component of the peroxisomal protein translocation machinery was genomically expressed in Flp-In-293 cells and purified from digitonin-solubilized membranes. Size-exclusion chromatography revealed the existence of distinct multimeric PEX14 assemblies at the peroxisomal membrane. Using mass spectrometric analysis, almost all known human peroxins involved in protein import were identified as constituents of the PEX14 complexes. Unexpectedly, tubulin was discovered to be the major PEX14-associated protein, and direct binding of the proteins was demonstrated. Accordingly, peroxisomal remnants in PEX14-deficient cells have lost their ability to move along microtubules. In vivo and in vitro analyses indicate that the physical binding to tubulin is mediated by the conserved N-terminal domain of PEX14. Thus, human PEX14 is a multi-tasking protein that not only facilitates peroxisomal protein import but is also required for peroxisome motility by serving as membrane anchor for microtubules.
The avian nidopallium caudolaterale is a multimodal area in the caudal telencephalon that is apparently not homologous to the mammalian prefrontal cortex but serves comparable functions. Here we analyzed binding-site densities of glutamatergic AMPA, NMDA and kainate receptors, GABAergic GABA(A), muscarinic M(1), M(2) and nicotinic (nACh) receptors, noradrenergic α(1) and α(2), serotonergic 5-HT(1A) and dopaminergic D(1)-like receptors using quantitative in vitro receptor autoradiography. We compared the receptor architecture of the pigeons' nidopallial structures, in particular the NCL, with cortical areas Fr2 and Cg1 in rats and prefrontal area BA10 in humans. Our results confirmed that the relative ratios of multiple receptor densities across different nidopallial structures (their "receptor fingerprints") were very similar in shape; however, the absolute binding densities (the "size" of the fingerprints) differed significantly. This finding enables a delineation of the avian NCL from surrounding structures and a further parcellation into a medial and a lateral part as revealed by differences in densities of nACh, M(2), kainate, and 5-HT(1A) receptors. Comparisons of the NCL with the rat and human frontal structures showed differences in the receptor distribution, particularly of the glutamate receptors, but also revealed highly conserved features like the identical densities of GABA(A), M(2), nACh and D(1)-like receptors. Assuming a convergent evolution of avian and mammalian prefrontal areas, our results support the hypothesis that specific neurochemical traits provide the molecular background for higher order processes such as executive functions. The differences in glutamate receptor distributions may reflect species-specific adaptations.
This article gives a detailed description of a protocol using density gradient centrifugation for the enrichment of neuromelanin granules and synaptosomes from low amounts (≥0.15 g) of human substantia nigra pars compacta tissue. This has a great advantage compared to already existing methods as it allows for the first time (i) a combined enrichment of neuromelanin granules and synaptosomes and (ii) just minimal amounts of tissue necessary to enable donor specific analysis. Individual specimens were classified as control or diseased according to clinical evaluation and neuropathological examination. For the enrichment of synaptosomes and neuromelanin granules from the same tissue sample density gradient centrifugations using Percoll® and Iodixanol were performed. The purity of resulting fractions was checked by transmission electron microscopy. We were able to establish a reproducible and easy to handle protocol combining two different density gradient centrifugations: using an Iodixanol gradient neuromelanin granules were enriched and in parallel, from the same sample, a fraction of synaptosomes with high purity using a Percoll® gradient was obtained. Our subfractionation strategy will enable a subsequent in depth proteomic characterization of neurodegenerative processes in the substantia nigra pars compacta in patients with Parkinson’s disease and dementia with Lewy bodies compared to appropriate controls.
Oxygen is essential to the human life and life of all aerobic organisms. The complete oxidation of nutrients for the biological energy supply is one of the most important prerequisites for the formation of higher life forms. However, cells that benefit from oxidative respiration also suffer from reactive oxygen species because they adapted to oxygen as an energy source. Healthy cells balance the formation and elimination of reactive oxygen species thereby creating and keeping reactive oxygen species-homeostasis. When the concentration of free radicals exceeds a critical level and homeostasis is disturbed, oxidative stress occurs leading to damage of multiple cellular molecules and compartments. Therefore, oxidative stress plays an important role in the physiology and pathology of various diseases. Often, the antioxidant protection system becomes pathologically unbalanced in the genesis of several diseases, leading to functional losses of the organism, as in the case of amyotrophic lateral sclerosis, or cells develop metabolic mechanisms to use this system as protection against external influences, such as in the case of glioblastoma cells. Either way, understanding the underlying deregulated mechanisms of the oxidative protection system would allow the development of novel treatment strategies for various diseases. Thus, regardless of the direction in which the reactive oxygen species-homeostasis disequilibrate, the focus should be on the oxidative protection system.
We have investigated the effects of taxol on the axonal transport of horseradish peroxidase (HRP) in dorsal root ganglia (DRG) cells and their neuronal cytoskeleton. The former were analysed by microinjection of HRP into single DRG cells and the latter was studied by means of immunohistochemistry and cryo-electron microscopy. In cultured and untreated DRG cells, microinjected HRP was typically transported anterogradely several hundred micrometres along their neurites. Different exposure periods (1, 2 and 3 days) to taxol were analysed. The axonal transport of HRP in DRG cells was time-dependently impeded by taxol. After the drug had been washed out, a recovery of the axonal transport of HRP was observed and confirmed by quantitative analysis. Cryo-electron microscopy revealed an abnormal aggregation of axonal and cytoplasmic microtubules, associated with a decreased amount of cross-linking structures, in taxol-treated DRG cell cultures. After 3 days of taxol exposure, microtubule-associated proteins and Tau-protein were restricted to the cellular somata but the neurofilament network and tubulin-proteins seemed to be unaffected. Our results demonstrate, for the first time, an inhibition of anterograde axonal transport of HRP in single neurons by taxol. This effect is reversible and seems not to be caused by cellular damage, but is rather a consequence of an altered organisation of microtubules and/or microtubule-associated proteins.
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