TorsinA is a membrane-associated AAA+ (ATPases associated with a variety of cellular activities) ATPase implicated in primary dystonia, an autosomal-dominant movement disorder. We reconstituted TorsinA and its cofactors in vitro and show that TorsinA does not display ATPase activity in isolation; ATP hydrolysis is induced upon association with LAP1 and LULL1, type II transmembrane proteins residing in the nuclear envelope and endoplasmic reticulum. This interaction requires TorsinA to be in the ATP-bound state, and can be attributed to the luminal domains of LAP1 and LULL1. This ATPase activator function controls the activities of other members of the Torsin family in distinct fashion, leading to an acceleration of the hydrolysis step by up to two orders of magnitude. The dystonia-causing mutant of TorsinA is defective in this activation mechanism, suggesting a loss-of-function mechanism for this congenital disorder.DYT1 dystonia | LINC complex | nuclear egress
Torsins are membrane-associated ATPases whose activity is dependent on two activating cofactors, lamina-associated polypeptide 1 (LAP1) and luminal domain-like LAP1 (LULL1). The mechanism by which these cofactors regulate Torsin activity has so far remained elusive. In this study, we identify a conserved domain in these activators that is predicted to adopt a fold resembling an AAA+ (ATPase associated with a variety of cellular activities) domain. Within these domains, a strictly conserved Arg residue present in both activating cofactors, but notably missing in Torsins, aligns with a key catalytic Arg found in AAA+ proteins. We demonstrate that cofactors and Torsins associate to form heterooligomeric assemblies with a defined Torsin-activator interface. In this arrangement, the highly conserved Arg residue present in either cofactor comes into close proximity with the nucleotide bound in the neighboring Torsin subunit. Because this invariant Arg is strictly required to stimulate Torsin ATPase activity but is dispensable for Torsin binding, we propose that LAP1 and LULL1 regulate Torsin ATPase activity through an active site complementation mechanism.DYT1 dystonia | nuclear envelope | ATPase | Torsin T orsin ATPases belong to the AAA+ (ATPase associated with a variety of cellular activities) superfamily of ATPases (1) but are unusual in that they lack conserved catalytic residues that are typically found in related ATPases (2, 3). Accordingly, Torsins do not display ATPase activity unless they are engaged by their regulatory cofactors lamina-associated polypeptide 1 (LAP1) or luminal domain-like LAP1 (LULL1) (4), which are type II transmembrane proteins residing in the nuclear envelope and endoplasmic reticulum (ER) (5, 6). This property stands in sharp contrast to the behavior of closely related Clp/Hsp100 ATPases, which display considerable basal ATPase activities that are moderately stimulated by their substrates (7,8). Although a number of Clp/Hsp100 proteins use distinct cofactors that confer substrate specificity to the typically hexameric ATPase ring, they operate via similar principles (9). Substrates ultimately engage the pore at the center of the oligomeric assembly. This narrow annulus is defined by pore loops that emanate from each subunit and harbor a conserved aromatic residue that defines the center of the pore (10). The energy of ATP hydrolysis is invested in threading the substrate through this axial channel, and the substrate is unfolded in the process (11).Much less is known about the mode of action of Torsin ATPases, although it is clear that regulation of Torsin activity is of vital importance in an organismal context. A mutation in TorsinA (TorA) causing the movement disorder primary dystonia (12) renders TorA unresponsive to its binding partners LAP1 and LULL1 (4), and a homozygous "knock-in" of this disease allele in mice causes a lethal phenotype, as does a TorA KO (13). A conditional deletion of TorA from the CNS in mice accurately replicates the symptoms of primary dystonia (14). In add...
Mobility and migration patterns of groups and individuals have long been a topic of interest to archaeologists, used for broad explanatory models of cultural change as well as illustrations of historical particularism. The 14th century AD was a tumultuous period of history in Britain, with severely erratic weather patterns, the Great Famine of 1315–1322, the Scottish Wars of Independence, and the Hundred Years' War providing additional migration pressures to the ordinary economic issues drawing individuals to their capital under more stable conditions. East Smithfield Black Death Cemetery (Royal Mint) had a documented use period of only 2 years (AD 1348–1350), providing a precise historical context (∼50 years) for data. Adults (n = 30) from the East Smithfield site were sampled for strontium and oxygen stable isotope analyses of tooth enamel. Five individuals were demonstrated to be statistical outliers through the combined strontium and oxygen isotope data. Potential origins for migrants ranged from London's surrounding hinterlands to distant portions of northern and western Britain. Historic food sourcing practices for London were found to be an important factor for consideration in a broader than expected 87Sr/86Sr range reflected in a comparison of enamel samples from three London datasets. The pooled dataset demonstrated a high level of consistency between site data, divergent from the geologically predicted range. We argue that this supports the premise that isotope data in human populations must be approached as a complex interaction between behavior and environment and thus should be interpreted cautiously with the aid of alternate lines of evidence. Am J Phys Anthropol, 2013. © 2012 Wiley Periodicals, Inc.
Torsin ATPases (Torsins) belong to the widespread AAA+ (ATPases associated with a variety of cellular activities) family of ATPases, which share structural similarity but have diverse cellular functions. Torsins are outliers in this family because they lack many characteristics of typical AAA+ proteins, and they are the only members of the AAA+ family located in the endoplasmic reticulum and contiguous perinuclear space. While it is clear that Torsins have essential roles in many, if not all metazoans, their precise cellular functions remain elusive. Studying Torsins has significant medical relevance since mutations in Torsins or Torsin-associated proteins result in a variety of congenital human disorders, the most frequent of which is Early Onset Torsion (DYT1) Dystonia, a severe movement disorder. A better understanding of the Torsin system is needed to define the molecular etiology of these diseases, potentially enabling corrective therapy. Here, we provide a comprehensive overview of the Torsin system in metazoans, discuss functional clues obtained from various model systems and organisms, and provide a phylogenetic and structural analysis of Torsins and their regulatory cofactors in relation to disease-causative mutations. Moreover, we review recent data that has led to a dramatically improved understanding of these machines at a molecular level, providing a foundation for investigating the molecular defects underlying the associated movement disorders. Lastly, we discuss our ideas on how recent progress may be utilized to inform future studies aimed at determining the cellular role(s) of these atypical molecular machines and their implications for dystonia treatment options.
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