Browsing by Author "Wakabayashi-Ito, Noriko"

Now showing 1 - 2 of 2
  • Thumbnail Image
    Item
    dtorsin, the Drosophila Ortholog of the Early-Onset Dystonia TOR1A (DYT1), Plays a Novel Role in Dopamine Metabolism
    (PLOS, 2011) Wakabayashi-Ito, Noriko; Doherty, Olugbenga M.; Moriyama, Hideaki; Breakefield, Xandra O.; Gusella, James F.; O'Donnell, Janis M.; Ito, Naoto; Harvard University; Massachusetts General Hospital; University of Alabama Tuscaloosa; University of Nebraska Lincoln; Harvard Medical School
    Dystonia represents the third most common movement disorder in humans. At least 15 genetic loci (DYT1-15) have been identified and some of these genes have been cloned. TOR1A (formally DYT1), the gene responsible for the most common primary hereditary dystonia, encodes torsinA, an AAA ATPase family protein. However, the function of torsinA has yet to be fully understood. Here, we have generated and characterized a complete loss-of-function mutant for dtorsin, the only Drosophila ortholog of TOR1A. Null mutation of the X-linked dtorsin was semi-lethal with most male flies dying by the pre-pupal stage and the few surviving adults being sterile and slow moving, with reduced cuticle pigmentation and thin, short bristles. Third instar male larvae exhibited locomotion defects that were rescued by feeding dopamine. Moreover, biochemical analysis revealed that the brains of third instar larvae and adults heterozygous for the loss-of-function dtorsin mutation had significantly reduced dopamine levels. The dtorsin mutant showed a very strong genetic interaction with Pu (Punch: GTP cyclohydrolase), the ortholog of the human gene underlying DYT14 dystonia. Biochemical analyses revealed a severe reduction of GTP cyclohydrolase protein and activity, suggesting that dtorsin plays a novel role in dopamine metabolism as a positive-regulator of GTP cyclohydrolase protein. This dtorsin mutant line will be valuable for understanding this relationship and potentially other novel torsin functions that could play a role in human dystonia.
  • Thumbnail Image
    Item
    Mutant human torsinA, responsible for early-onset dystonia, dominantly suppresses GTPCH expression, dopamine levels and locomotion in Drosophila melanogaster
    (Company of Biologists, 2015) Wakabayashi-Ito, Noriko; Ajjuri, Rami R.; Henderson, Benjamin W.; Doherty, Olugbenga M.; Breakefield, Xandra O.; O'Donnell, Janis M.; Ito, Naoto; Harvard University; Massachusetts General Hospital; Harvard Medical School; University of Alabama Tuscaloosa
    Dystonia represents the third most common movement disorder in humans with over 20 genetic loci identified. TOR1A (DYT1), the gene responsible for the most common primary hereditary dystonia, encodes torsinA, an AAA ATPase family protein. Most cases of DYT1 dystonia are caused by a 3 bp (Delta GAG) deletion that results in the loss of a glutamic acid residue (Delta E302/303) in the carboxyl terminal region of torsinA. This torsinA Delta E mutant protein has been speculated to act in a dominant-negative manner to decrease activity of wild type torsinA. Drosophila melanogaster has a single torsin-related gene, dtorsin. Null mutants of dtorsin exhibited locomotion defects in third instar larvae. Levels of dopamine and GTP cyclohydrolase (GTPCH) proteins were severely reduced in dtorsin-null brains. Further, the locomotion defect was rescued by the expression of human torsinA or feeding with dopamine. Here, we demonstrate that human torsinA Delta E dominantly inhibited locomotion in larvae and adults when expressed in neurons using a pan-neuronal promoter Elav. Dopamine and tetrahydrobiopterin (BH4) levels were significantly reduced in larval brains and the expression level of GTPCH protein was severely impaired in adult and larval brains. When human torsinA and torsinA Delta E were co-expressed in neurons in dtorsin-null larvae and adults, the locomotion rates and the expression levels of GTPCH protein were severely reduced. These results support the hypothesis that torsinA Delta E inhibits wild type torsinA activity. Similarly, neuronal expression of a Drosophila Dtorsin Delta E equivalent mutation dominantly inhibited larval locomotion and GTPCH protein expression. These results indicate that both torsinA Delta E and DtorsinDE act in a dominant-negative manner. We also demonstrate that Dtorsin regulates GTPCH expression at the post-transcriptional level. This Drosophila model of DYT1 dystonia provides an important tool for studying the differences in the molecular function between the wild type and the mutant torsin proteins.