Abstract
TorsinA is a AAA+ ATPase involved in the severe neurological disease Early Onset Torsion Dystonia. Despite the impressive progress in the field in the recent years, the structural organization and function of this intriguing molecule is still not clear. One outstanding difference between torsinA and other AAA+ ATPases is that torsinA is a glycoprotein. TorsinA N-linked glycans impact torsinA biogenesis and subcellular localization. Here, we propose that torsinA glycans also modulate torsinA oligomerization properties. We used structural modeling to test this idea, and show that N-linked glycans appear to restrict torsinA’s ability to form closed homohexameric ring assemblies, and instead promote an open hexameric conformation that allows torsinA interaction with key cofactors required for ATP hydrolysis. This mechanism would make torsinA a prime example of Nature’s sophisticated molecular glycoengineering.
Introduction
TorsinA is an Endoplasmic Reticulum (ER) AAA+ ATPase associated with the development of the neurological disease Early-Onset Torsion Dystonia (EOTD) (Gonzalez-Alegre, 2019). TorsinA structure and function, and its role in EOTD onset are still controversial (Rose et al., 2015; Chase et al., 2017a). TorsinA is a rather unusual ATPase, as it lacks the AAA+ ATPase conserved hydrophobic pore loops involved in substrate unfolding and remodeling and the arginine finger required for ATP hydrolysis (Brown et al., 2014; Sosa et al., 2014; Demircioglu et al., 2016). In fact, the ATP hydrolysis activity of torsinA requires binding to the ER and Nuclear Envelope-type II transmembrane proteins LULL1 and LAP1, respectively (Zhao et al., 2013; Brown et al., 2014; Sosa et al., 2014). Further, AAA+ ATPases generally adopt hexameric conformations (Hanson and Whiteheart, 2005), but torsinA oligomerization status is still under debate. TorsinA has been proposed to form a homohexameric structure, and/or a heterohexameric structure with LULL1/LAP1, and/or a homopolymeric filament structure (Vander Heyden et al., 2009; Jungwirth et al., 2010; Zhao et al., 2013; Brown et al., 2014; Li et al., 2014; Sosa et al., 2014; Demircioglu et al., 2016, 2019; Chase et al., 2017a,b). It is unclear whether any of these oligomers reflect the physiological conformation of torsinA, and if torsinA can dynamically transition from one to another.
Critically, the proposed polymeric structures for torsinA do not take into account one fundamental molecular characteristic of torsinA: that torsinA is a glycoprotein. TorsinA has two sites for N-linked glycosylation located between the ATP binding and hydrolysis Walker domains (Ozelius et al., 1997; Figure 1). Both N-linked glycosylation sites are occupied in torsinA (Hewett et al., 2000, 2003; Kustedjo et al., 2000; Bragg et al., 2004; Gonzalez-Alegre and Paulson, 2004; Vander Heyden et al., 2011; Zacchi et al., 2014; Zhao et al., 2016). The N158VS N-linked glycosylation site is highly conserved in torsinA homologs across different species (Figures 1A,B) and in the other three torsinA human homologs (Figure 1C; Ozelius et al., 1999; Zhu et al., 2008; Granata et al., 2009; Demircioglu et al., 2016), while the N143IT glycosylation site is less conserved (Figure 1). N-linked glycans are heavily involved in protein folding and quality control (Aebi, 2013; Caramelo and Parodi, 2015; Zacchi et al., 2016). Indeed, torsinA requires at least one N-linked glycan for stability (Hewett et al., 2003; Zacchi et al., 2014). Interestingly, glycosylation at N158VS is selectively required to stabilize the EOTD-associated torsinAΔE variant (Zacchi et al., 2014) and mutation of this site reverts the aberrant torsinAΔE subcellular localization (Bragg et al., 2004). Therefore, N-linked glycans are key post-translational modifications for torsinA biogenesis. N-linked glycans are bulky and hydrophilic molecules (Varki, 2017) and, in addition to their role in folding and quality control, N-linked glycans can restrict the formation of quaternary structures in proteins (Medus et al., 2017). This conformation-shaping effect has been well documented for immunoglobulin G (Nagae and Yamaguchi, 2012; Higel et al., 2016). Hence, N-linked glycans could also influence torsinA ability to form hexamers or filaments and interact with membranes and other proteins, impacting torsinA function.
FIGURE 1
Results and Discussion
Modeling diverse oligomerization states of glycosylated torsinA supports the intriguing hypothesis that N-linked glycans play a fundamental structural and functional role in torsinA (Figure 2). To generate these models, we used the torsinA-LULL1 heterodimer crystal structure (PDB 5J1S) (Demircioglu et al., 2016). The torsinA-LULL1 structure displays torsinA without the transmembrane domain (TMD) and the ER lumenal (C-terminal) domain of LULL1 with the N-terminal residues that follow the TMD (Demircioglu et al., 2016). We modeled the position of the N-linked glycans in torsinA based on this structure by attaching typical ER high mannose N-linked glycans at Asn143 and Asn158 (Hewett et al., 2000; Kustedjo et al., 2000; Aebi, 2013; Figure 2). In this model, the Asn158 glycan would be oriented parallel to the TMD, potentially facing the ER membrane while the Asn143 glycan would protrude from torsinA in a close to 90° angle (Figure 2A). Due to their position in the folded protein, torsinA N-linked glycans would not impact heterodimerization with the LULL1/LAP1 cofactors (Figure 2A), as expected for this physiological interaction. However, structural modeling suggests that the Asn143 glycan would prevent homo- and heterohexameric closed ring assemblies, as these glycans appear to face the constricted space of the central opening of the ring (Figures 2B,C, 3). Interestingly, this glycomolecular crowding would not be an issue for torsinB, torsinA’s paralog (Ozelius et al., 1999; Hewett et al., 2004), since the N143IT glycosylation site is not conserved in torsinB (Figure 1C). Instead, torsinB contains a glycosylation site at Asn64, which is not oriented towards the inner ring but rather towards the outer perimeter (Figure 2D), potentially allowing for the formation of closed torsinB homohexameric rings (Figure 2D). The molecular crowding of Asn143N-linked glycans in this region of torsinA can be resolved when modeling torsinA homohexamers based on extended (Figures 2C, 3A) and open (Figure 3B) structural conformations of the homologous AAA ATPase Hsp104 (Lee et al., 2019). In these scenarios, the respective glycans would be accommodated by a slightly larger central opening and a pitch that results from a lock-washer-like conformation moving individual Asn143 residues out of plane. Similarly, glycan chains at Asn143 could be seamlessly accommodated by the larger central pore of torsinA filaments (Demircioglu et al., 2019; Figure 2E). However, Asn158 glycans would most likely prevent further polymerization due to geometrical restrictions that arise from interactions of torsinA molecules in consecutive turns of the ring which essentially block access to Asn158 (Figure 2E). Therefore, the presence of N-linked glycosylation on Asn143 and Asn158 may promote assembly of torsinA into the proposed open homohexameric ring structures in vivo (Chase et al., 2017a,b). Intriguingly, this model would provide a basis to reconcile observations of homohexameric torsinA complexes with the fact that monomers need to be accessible for binding LULL1/LAP1 cofactors to exert their enzymatic function (Li et al., 2014; Chase et al., 2017a,b; Figure 3C). Based on our observations, we propose that fully glycosylated torsinA can only assemble into extended (Figure 3A) or open (Figure 3B) hexameric structures upon binding ATP (Chase et al., 2017b). These complexes would be stabilized by the presence of the Asn143 and Asn158 glycans that prohibit closed ring structures or further polymerization into filaments. The transition between extended and open forms may be dynamic or could be triggered by interactions with the torsinA cofactor LULL1/LAP1 but, ultimately, an open conformation would be required to accommodate the torsinA-LULL1 heterodimer at the penultimate position of the complex (see Figure 3C for a model of the proposed transient heteroheptameric torsinA-LULL1 complex) (Chase et al., 2017a,b). Binding of the cofactor results in ATP hydrolysis, concomitant with ring dissassembly and loss of the torsinA subunit (Chase et al., 2017b).
FIGURE 2
FIGURE 3
Notably, glycosylation is not required for torsinA oligomerization, as bacterially expressed torsinA can assemble into hexamers and filaments (Sosa et al., 2014; Demircioglu et al., 2016, 2019) [although important caveats to the bacterial expression system that question the physiological relevance of these structures have been pointed out (Chase et al., 2017b; Demircioglu et al., 2019)]. Further, open ring conformations are naturally adopted by multiple other (cytosolic) AAA+ ATPases (Dong et al., 2019; Lee et al., 2019; Gates and Martin, 2020; Lopez et al., 2020), indicating that N-linked glycosylation is not required to generate open ring conformations. However, when present, torsinA N-linked glycans would ensure that this unusual ATPase maintains the open/extended oligomeric conformation required for LAP1/LULL1-dependent ATP hydrolysis by preventing the formation of closed ring assemblies. Therefore, torsinA N-linked glycans would play an essential role in modulating torsinA oligomerization and function.
The potential impact of N-linked glycans on torsinA oligomerization would add another layer of complexity into the regulation of torsinA function. In this context, genetic or environmental factors that lead to defects in protein translocation into the ER, in protein glycosylation, or in glycan-dependent folding or quality control would impact torsinA ability to form closed or open hexamers and, in turn, its ability to interact with its cofactors. Considering the delicate equilibrium that governs ER homeostasis, how torsinA N-linked glycosylation is sensitive to redox changes and to defects in certain ER chaperones and enzymes (Zacchi et al., 2014), and how accessibility to these enzymes and chaperones could vary throughout cell development or due to cell type or subcompartment localization (Shenkman and Lederkremer, 2019; Almeida and Amaral, 2020), it is tempting to speculate that N-linked glycans offer torsinA the key to a dynamic conformational and functional molecular polymorphism.
N-linked glycans are highly diverse structures that play myriad of functional roles in the cell (Varki, 2017). N-linked glycans are usually studied in the context of protein quality control during folding and biogenesis, of genetic diseases, and due to their role in immunological responses and microbial pathogenesis. However, it is becoming increasingly clear that the occupancy and structural heterogeneity of the glycans play fundamental structural and physiological roles (Higel et al., 2016; Zacchi and Schulz, 2016; Medus et al., 2017). Here, we highlight the key function of N-linked glycans in shaping the conformation and structure of protein complexes (Medus et al., 2017), and hypothesize that their presence or absence dramatically impact torsinA oligomerization by introducing sterical restrictions. The last decades have seen phenomenal advances in protein and glycan structural characterization technologies. The combination of both fields of studies will not only unravel the quaternary structure of this fascinating protein, but will also provide an exciting new magnifying glass into biology.
Statements
Data availability statement
Publicly available datasets were analyzed in this study. This data can be found here: All datasets used are available in https://www.rcsb.org/. The specific datasets used in this work are: PDB ID 5J1S, PDB ID 6OIF, PDB ID 6N8T, PDB ID 3PXI, PDB ID 6N8Z, and PDB ID 6N8V.
Author contributions
CF and LZ were involved in all aspects of this work regarding conception and design, data analysis and interpretation, writing and editing of the manuscript, and made the figures. CF performed the structural modeling. Both authors contributed to the article and approved the submitted version.
Funding
This work was funded by the Australian Research Council Industrial Transformation Training Centre IC160100027. LZ holds a Promoting Women Fellowship from the University of Queensland.
Acknowledgments
We are grateful to Prof. Alan Rowan and Prof. Stephen Mahler from the University of Queensland for their support and to Prof. Jeffrey Brodsky from the University of Pittsburgh for suggestions and advise.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
References
1
AebiM. (2013). N-linked protein glycosylation in the ER.Biochim. Biophys. Acta18332430–2437. 10.1016/j.bbamcr.2013.04.001
2
AlmeidaC.AmaralM. D. (2020). A central role of the endoplasmic reticulum in the cell emerges from its functional contact sites with multiple organelles.Cell. Mol. Life Sci.10.1007/s00018-020-03523-w[Epub ahead of print].
3
BraggD. C.KaufmanC. A.KockN.BreakefieldX. O. (2004). Inhibition of N-linked glycosylation prevents inclusion formation by the dystonia-related mutant form of torsinA.Mol. Cell. Neurosci.27417–426. 10.1016/j.mcn.2004.07.009
4
BrownR. S.ZhaoC.ChaseA. R.WangJ.SchliekerC. (2014). The mechanism of Torsin ATPase activation.Proc. Natl. Acad. Sci. U.S.A.111E4822–E4831. 10.1073/pnas.1415271111
5
CarameloJ. J.ParodiA. J. (2015). A sweet code for glycoprotein folding.FEBS Lett.5893379–3387. 10.1016/j.febslet.2015.07.021
6
ChaseA. R.LaudermilchE.SchliekerC. (2017a). Torsin ATPases: harnessing dynamic instability for function.Front. Mol. Biosci.4:29. 10.3389/fmolb.2017.00029
7
ChaseA. R.LaudermilchE.WangJ.ShigematsuH.YokoyamaT.SchliekerC. (2017b). Dynamic functional assembly of the Torsin AAA+ ATPase and its modulation by LAP1.Mol. Biol. Cell.282765–2772. 10.1091/mbc.E17-05-0281
8
CrooksG. E.HonG.ChandoniaJ.-M.BrennerS. E. (2004). WebLogo: a sequence logo generator.Genome Res.14, 1188–1190. 10.1101/gr.849004
9
DemirciogluF. E.SosaB. A.IngramJ.PloeghH. L.SchwartzT. U. (2016). Structures of TorsinA and its disease-mutant complexed with an activator reveal the molecular basis for primary dystonia.eLife5:e17983. 10.7554/eLife.17983
10
DemirciogluF. E.ZhengW.McQuownA. J.MaierN. K.WatsonN.CheesemanI. M.et al (2019). The AAA + ATPase TorsinA polymerizes into hollow helical tubes with 8.5 subunits per turn.Nat. Commun.10:3262. 10.1038/s41467-019-11194-w
11
DongY.ZhangS.WuZ.LiX.WangW. L.ZhuY.et al (2019). Cryo-EM structures and dynamics of substrate-engaged human 26S proteasome.Nature56549–55. 10.1038/s41586-018-0736-4
12
GatesS. N.MartinA. (2020). Stairway to translocation: AAA+ motor structures reveal the mechanisms of ATP-dependent substrate translocation.Protein Sci.29407–419. 10.1002/pro.3743
13
Gonzalez-AlegreP. (2019). Advances in molecular and cell biology of dystonia: focus on torsinA.Neurobiol. Dis.127233–241. 10.1016/j.nbd.2019.03.007
14
Gonzalez-AlegreP.PaulsonH. L. (2004). Aberrant cellular behavior of mutant torsinA implicates nuclear envelope dysfunction in DYT1 dystonia.J. Neurosci.242593–2601. 10.1523/jneurosci.4461-03.2004
15
GranataA.SchiavoG.WarnerT. T. (2009). TorsinA and dystonia: from nuclear envelope to synapse.J. Neurochem.1091596–1609. 10.1111/j.1471-4159.2009.06095.x
16
HansonP. I.WhiteheartS. W. (2005). AAA+ proteins: have engine, will work.Nat. Rev. Mol. Cell. Biol.6519–529. 10.1038/nrm1684
17
HewettJ.Gonzalez-AgostiC.SlaterD.ZieferP.LiS.BergeronD.et al (2000). Mutant torsinA, responsible for early-onset torsion dystonia, forms membrane inclusions in cultured neural cells.Hum. Mol. Genet.91403–1413. 10.1093/hmg/9.9.1403
18
HewettJ.ZieferP.BergeronD.NaismithT.BostonH.SlaterD.et al (2003). TorsinA in PC12 cells: localization in the endoplasmic reticulum and response to stress.J. Neurosci. Res.72158–168. 10.1002/jnr.10567
19
HewettJ. W.KammC.BostonH.BeauchampR.NaismithT.OzeliusL.et al (2004). TorsinB–perinuclear location and association with torsinA.J. Neurochem.891186–1194. 10.1111/j.1471-4159.2004.02404.x
20
HigelF.SeidlA.SorgelF.FriessW. (2016). N-glycosylation heterogeneity and the influence on structure, function and pharmacokinetics of monoclonal antibodies and Fc fusion proteins.Eur. J. Pharm. Biopharm.10094–100. 10.1016/j.ejpb.2016.01.005
21
JungwirthM.DearM. L.BrownP.HolbrookK.GoodchildR. (2010). Relative tissue expression of homologous torsinB correlates with the neuronal specific importance of DYT1 dystonia-associated torsinA.Hum. Mol. Genet.19888–900. 10.1093/hmg/ddp557
22
KriegerE.JooK.LeeJ.LeeJ.RamanS.ThompsonJ.et al (2009). Improving physical realism, stereochemistry, and side-chain accuracy in homology modeling: four approaches that performed well in CASP8.Proteins77(Suppl. 9), 114–122. 10.1002/prot.22570
23
KustedjoK.BraceyM. H.CravattB. F. (2000). Torsin A and its torsion dystonia-associated mutant forms are lumenal glycoproteins that exhibit distinct subcellular localizations.J. Biol. Chem.27527933–27939.
24
LeeS.RohS. H.LeeJ.SungN.LiuJ.TsaiF. T. F. (2019). Cryo-EM structures of the Hsp104 protein disaggregase captured in the ATP conformation.Cell. Rep.2629.e3–36.e3. 10.1016/j.celrep.2018.12.037
25
LiH.WuH.-C.LiuZ.ZacchiL. F.BrodskyJ. L.ZolkiewskiM. (2014). Intracellular complexes of the early-onset torsion dystonia-associated AAA+ ATPase TorsinA.SpringerPlus3:743. 10.1186/2193-1801-3-743
26
LopezK. E.RizoA. N.TseE.LinJ.ScullN. W.ThwinA. C.et al (2020). Conformational plasticity of the ClpAP AAA+ protease couples protein unfolding and proteolysis.Nat. Struct. Mol. Biol.27406–416. 10.1038/s41594-020-0409-5
27
MedusM. L.GomezG. E.ZacchiL. F.CoutoP. M.LabriolaC. A.LabandaM. S.et al (2017). N-glycosylation triggers a dual selection pressure in eukaryotic secretory proteins.Sci. Rep.7:8788. 10.1038/s41598-017-09173-6
28
NagaeM.YamaguchiY. (2012). Function and 3D structure of the N-glycans on glycoproteins.Int. J. Mol. Sci.138398–8429. 10.3390/ijms13078398
29
OzeliusL. J.HewettJ. W.PageC. E.BressmanS. B.KramerP. L.ShalishC.et al (1997). The early-onset torsion dystonia gene (DYT1) encodes an ATP-binding protein.Nat. Genet.1740–48. 10.1038/ng0997-40
30
OzeliusL. J.PageC. E.KleinC.HewettJ. W.MinetaM.LeungJ.et al (1999). The TOR1A (DYT1) gene family and its role in early onset torsion dystonia.Genomics62377–384. 10.1006/geno.1999.6039
31
ParkS. J.LeeJ.QiY.KernN. R.LeeH. S.JoS.et al (2019). CHARMM-GUI Glycan Modeler for modeling and simulation of carbohydrates and glycoconjugates.Glycobiology29320–331. 10.1093/glycob/cwz003
32
RoseA. E.BrownR. S.SchliekerC. (2015). Torsins: not your typical AAA+ ATPases.Crit. Rev. Biochem. Mol. Biol.50532–549. 10.3109/10409238.2015.1091804
33
ShenkmanM.LederkremerG. Z. (2019). Compartmentalization and selective tagging for disposal of misfolded glycoproteins.Trends Biochem. Sci.44827–836. 10.1016/j.tibs.2019.04.012
34
SosaB. A.DemirciogluF. E.ChenJ. Z.IngramJ.PloeghH. L.SchwartzT. U. (2014). How lamina-associated polypeptide 1 (LAP1) activates torsin.eLife3:e03239. 10.7554/eLife.03239
35
Vander HeydenA. B.NaismithT. V.SnappE. L.HansonP. I. (2011). Static retention of the lumenal monotopic membrane protein torsinA in the endoplasmic reticulum.EMBO J.303217–3231. 10.1038/emboj.2011.233
36
Vander HeydenA. B.NaismithT. V.SnappE. L.HodzicD.HansonP. I. (2009). LULL1 retargets TorsinA to the nuclear envelope revealing an activity that is impaired by the DYT1 dystonia mutation.Mol. Biol. Cell.202661–2672. 10.1091/mbc.E09-01-0094
37
VarkiA. (2017). Biological roles of glycans.Glycobiology273–49. 10.1093/glycob/cww086
38
WebbB.SaliA. (2016). Comparative protein structure modeling using MODELLER.Curr. Protoc. Bioinformatics545.6.1–5.6.37. 10.1002/cpbi.3
39
ZacchiL. F.CarameloJ. J.McCrackenA. A.BrodskyJ. L. (2016). “Endoplasmic reticulum associated degradation and protein quality control,” in The Encyclopedia of Cell Biology, 1st Edn, ed.StahlR. B. A. P. (Waltham, MA: Academic Press), 596–611. 10.1016/b978-0-12-394447-4.10072-0
40
ZacchiL. F.SchulzB. L. (2016). N-glycoprotein macroheterogeneity: biological implications and proteomic characterization.Glycoconj. J.33359–376. 10.1007/s10719-015-9641-3
41
ZacchiL. F.WuH. C.BellS. L.MillenL.PatonA. W.PatonJ. C.et al (2014). The BiP molecular chaperone plays multiple roles during the biogenesis of torsinA, an AAA+ ATPase associated with the neurological disease early-onset torsion dystonia.J. Biol. Chem.28912727–12747. 10.1074/jbc.M113.529123
42
ZhaoC.BrownR. S.ChaseA. R.EiseleM. R.SchliekerC. (2013). Regulation of Torsin ATPases by LAP1 and LULL1.Proc. Natl. Acad. Sci. U.S.A.110E1545–E1554. 10.1073/pnas.1300676110
43
ZhaoC.BrownR. S.TangC. H.HuC. C.SchliekerC. (2016). Site-specific proteolysis mobilizes TorsinA from the membrane of the endoplasmic reticulum (ER) in response to ER stress and B cell stimulation.J. Biol. Chem.2919469–9481. 10.1074/jbc.M115.709337
44
ZhuL.WrablJ. O.HayashiA. P.RoseL. S.ThomasP. J. (2008). The torsin-family AAA+ protein OOC-5 contains a critical disulfide adjacent to Sensor-II that couples redox state to nucleotide binding.Mol. Biol. Cell.193599–3612. 10.1091/mbc.e08-01-0015
Summary
Keywords
torsinA, glycans, AAA ATPase, modeling, structure
Citation
Fercher C and Zacchi LF (2020) Resolving the TorsinA Oligomerization Conundrum: The Glycan Hypothesis. Front. Mol. Biosci. 7:585643. doi: 10.3389/fmolb.2020.585643
Received
21 July 2020
Accepted
14 September 2020
Published
02 October 2020
Volume
7 - 2020
Edited by
Anastassios C. Papageorgiou, University of Turku, Finland
Reviewed by
Nicolas Joly, UMR 7592 Institut Jacques Monod (IJM), France; Michal Zolkiewski, Kansas State University, United States
Updates
Copyright
© 2020 Fercher and Zacchi.
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Lucía F. Zacchi, l.zacchi@uq.edu.au
This article was submitted to Structural Biology, a section of the journal Frontiers in Molecular Biosciences
Disclaimer
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.