Abstract
Autosomal-dominant, early-onset DYT1 dystonia is associated with an in-frame deletion of a glutamic acid codon (ΔE) in the TOR1A gene. The gene product, torsinA, is an evolutionarily conserved AAA+ ATPase. The fact that constitutive secretion from patient fibroblasts is suppressed indicates that the ΔE-torsinA protein influences the cellular secretory machinery. However, which component is affected remains unclear. Prompted by recent reports that abnormal protein trafficking through the Golgi apparatus, the major protein-sorting center of the secretory pathway, is sometimes associated with a morphological change in the Golgi, we evaluated the influence of ΔE-torsinA on this organelle. Specifically, we examined its structure by confocal microscopy, in cultures of striatal, cerebral cortical and hippocampal neurons obtained from wild-type, heterozygous and homozygous ΔE-torsinA knock-in mice. In live neurons, the Golgi was assessed following uptake of a fluorescent ceramide analog, and in fixed neurons it was analyzed by immuno-fluorescence staining for the Golgi-marker GM130. Neither staining method indicated genotype-specific differences in the size, staining intensity, shape or localization of the Golgi. Moreover, no genotype-specific difference was observed as the neurons matured in vitro. These results were supported by a lack of genotype-specific differences in GM130 expression levels, as assessed by Western blotting. The Golgi was also disrupted by treatment with brefeldin A, but no genotype-specific differences were found in the immuno-fluorescence staining intensity of GM130. Overall, our results demonstrate that the ΔE-torsinA protein does not drastically influence Golgi morphology in neurons, irrespective of genotype, brain region (among those tested), or maturation stage in culture. While it remains possible that functional changes in the Golgi exist, our findings imply that any such changes are not severe enough to influence its morphology to a degree detectable by light microscopy.
Highlights
The Golgi apparatus is an intracellular, membrane-bounded organelle, and it is involved in protein-lipid modification as well as in trafficking of transport vesicles from the endoplasmic reticulum (ER) to the plasma membrane [1,2,3,4]
DYT1 dystonia is caused by a mutation in the TOR1A gene (c.904_906delGAG/907_909delGAG; p.Glu302del/Glu303del; TOR1AΔE), which encodes the protein torsinA; this mutation results in an in-frame deletion of a codon for glutamic acid (ΔE-torsinA) [28, 29]
Live-cell staining of the Golgi apparatus in cultured hippocampal neurons
Summary
The Golgi apparatus is an intracellular, membrane-bounded organelle, and it is involved in protein-lipid modification as well as in trafficking of transport vesicles from the endoplasmic reticulum (ER) to the plasma membrane [1,2,3,4]. The Golgi is increasingly recognized as an organizing center for microtubules [5, 6], indicating that its function can affect a broad spectrum of trafficking phenomena along the microtubules In neurons, it resides mainly in the soma, near the nucleus (paranuclear Golgi apparatus) [7], where it is crucial for the transport of specific proteins to dendrites and axons [8,9,10]. DYT1 dystonia is a developmental neurological disorder that affects the brain [15,16,17] and was recently classified as a part of "early-onset generalized isolated dystonia" [18]. The details of how ΔE-torsinA influences the mammalian central neurons are still not well understood
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