{"id":4885,"date":"2021-07-19T14:03:10","date_gmt":"2021-07-19T12:03:10","guid":{"rendered":"https:\/\/biochemie2.uni-goettingen.de\/?page_id=4885"},"modified":"2025-12-01T17:35:49","modified_gmt":"2025-12-01T16:35:49","slug":"publications-schwappach-pignataro","status":"publish","type":"page","link":"https:\/\/biochemie.uni-goettingen.de\/index.php\/publications-schwappach-pignataro\/","title":{"rendered":"Publications (Schwappach-Pignataro)"},"content":{"rendered":"

Publications (since 2003)<\/b><\/h3>\n

2025<\/b>
\nBykov YS, Fenech EJ, Schwappach B. (2025) Highlight: organelles on and off the map: diversity, specialization and subdomains. Biol Chem.<\/b> 2025 Dec 1.<\/a>
\nSchwappach B. (2025) Machines like us scientists? : AI tools for mining the scientific literature in basic biomedical science. EMBO Rep.<\/b> 2025 Jul 10.<\/a><\/p>\n

2023<\/b>
\nMcDowell MA, Heimes M, Enkavi G, Farkas \u00c1, Saar D, Wild K, Schwappach B, Vattulainen I, Sinning I (2023) The GET insertase exhibits conformational plasticity and induces membrane thinning. Nat Commun<\/b> 14, 7355.<\/a><\/p>\n

2022<\/b>
\nBallin M, Griep W, Patel M, Karl M, Mentrup T, Rivera-Monroy J, Foo B, Schwappach B, Schr\u00f6der B (2022) The intramembrane proteases SPPL2a and SPPL2b regulate the homeostasis of selected SNARE proteins. FEBS J<\/b> 290(9):2320-2337.<\/a><\/p>\n

Ulrich K, Farkas \u00c1, Chan O, Katamanin O, Schwappach B, Jakob U (2022) From guide to guard-activation mechanism of the stress-sensing chaperone Get3. Mol Cell<\/b> 82(17):3226-3238.e7.<\/a><\/p>\n

Farkas \u00c1, Urlaub H, Bohnsack KE, Schwappach B (2022) Regulated targeting of the monotopic hairpin membrane protein Erg1 requires the GET pathway. J Cell Biol<\/b> 221(6):e202201036.<\/a><\/p>\n

2021<\/b>
\nGomkale R, Linden A, Neumann P, Schendzielorz AB, Stoldt S, Dybkov O, Kilisch M, Schulz C, Cruz-Zaragoza LD, Schwappach B, Ficner R, Jakobs S, Urlaub H, Rehling P (2021) Mapping protein interactions in the active TOM-TIM23 supercomplex. Nat Commun<\/b> 12, 5715.<\/a><\/p>\n

Kusch H, Kossen R, Suhr M, Freckmann L, Weber L, Henke C, Lehmann C, Rheinl\u00e4nder S, Aschenbrandt G, K\u00fchlborn LK, Marzec B, Menzel J, Schwappach B, Zelaray\u00e1n LC, Cyganek L, Antonios G, Kohl T, Lehnart SE, Zoremba M, Sax U, Nussbeck SY (2021) Management of Metadata Types in Basic Cardiological Research. Stud Health Technol Inform<\/b> 283, 59-68.<\/a><\/p>\n

Zhang Y, De Laurentiis E, Bohnsack KE, Wahlig M, Ranjan N, Gruseck S, Hackert P, W\u00f6lfle T, Rodnina MV, Schwappach B, Rospert S (2021) Ribosome-bound Get4\/5 facilitates the capture of tail-anchored proteins by Sgt2 in yeast. Nat Commun<\/b> 12, 782.<\/a><\/p>\n

Zhang H, Hanson A, de Almeida TS, Emfinger C, McClenaghan C, Harter T, Yan Z, Cooper PE, Brown GS, Arakel EC, Mecham RP, Kovacs A, Halabi CM, Schwappach B, Remedi MS, Nichols CG (2021) Complex consequences of Cantu syndrome SUR2 variant R1154Q in genetically modified mice. JCI Insight<\/b> 6(5):e145934.<\/a><\/p>\n

Asseck LY, Mehlhorn DG, Monroy JR, Ricardi MM, Breuninger H, Wallmeroth N, Berendzen KW, Nowrousian M, Xing S, Schwappach B, Bayer M, Grefen C (2021) Endoplasmic reticulum membrane receptors of the GET pathway are conserved throughout eukaryotes. Proc Natl Acad Sci U S A<\/b> 118(1):e2017636118.<\/a><\/p>\n

Kraxner J, Lorenz C, Menzel J, Parfentev I, Silbern I, Denz M, Urlaub H, Schwappach B, K\u00f6ster S (2021) Post-translational modifications soften vimentin intermediate filaments. Nanoscale<\/b> 13, 380-387.<\/a><\/p>\n

Ulrich K, Schwappach B, Jakob U (2021) Thiol-based switching mechanisms of stress-sensing chaperones. Biol Chem<\/b> 402, 239-252.<\/a><\/p>\n

Fakuade FE, Steckmeister V, Seibertz F, Gronwald J, Kestel S, Menzel J, Pronto JRD, Taha K, Haghighi F, Kensah G, Pearman CM, Wiedmann F, Teske AJ, Schmidt C, Dibb KM, El-Essawi A, Danner BC, Baraki H, Schwappach B, Kutschka I, Mason FE, Voigt N (2021) Altered atrial cytosolic calcium handling contributes to the development of postoperative atrial fibrillation. Cardiovasc Res<\/b> 117, 1790-1801.<\/a><\/p>\n

2020<\/b>
\nMcDowell MA, Heimes M, Fiorentino F, Mehmood S, Farkas \u00c1, Coy-Vergara J, Wu D, Bolla JR, Schmid V, Heinze R, Wild K, Flemming D, Pfeffer S, Schwappach B, Robinson CV, Sinning I (2020) Structural Basis of Tail-Anchored Membrane Protein Biogenesis by the GET Insertase Complex. Mol Cell<\/b> 80, 72-86.e7.<\/a><\/p>\n

Menzel J, Kownatzki-Danger D, Tokar S, Ballone A, Unthan-Fechner K, Kilisch M, Lenz C, Urlaub H, Mori M, Ottmann C, Shattock MJ, Lehnart SE, Schwappach B (2020) 14-3-3 binding creates a memory of kinase action by stabilizing the modified state of phospholamban. Sci Signal<\/b> 13(647):eaaz1436.<\/a><\/p>\n

Schwappach B (2020) Chloride accumulation in endosomes and lysosomes: facts checked in mice. EMBO J<\/b> 39, e104812.<\/a><\/p>\n

Kilisch M, Mayer S, Mitkovski M, Roehse H, Hentrich J, Schwappach B, Papadopoulos T (2020) A GTPase-induced switch in phospholipid affinity of collybistin contributes to synaptic gephyrin clustering. J Cell Sci<\/b> 133(2):jcs232835.<\/a><\/p>\n

2019<\/b>
\nArakel EC, Huranova M, Estrada AF, Rau EM, Spang A, Schwappach B (2019) Dissection of GTPase-activating proteins reveals functional asymmetry in the COPI coat of budding yeast. J Cell Sci<\/b> 132(16):jcs232124.<\/a><\/p>\n

Borgese N, Coy-Vergara J, Colombo SF, Schwappach B (2019) The Ways of Tails: the GET Pathway and more. Protein J<\/b> 38, 289-305.<\/a><\/p>\n

Coy-Vergara J, Rivera-Monroy J, Urlaub H, Lenz C, Schwappach B (2019) A trap mutant reveals the physiological client spectrum of TRC40. J Cell Sci<\/b> 132(13):jcs230094.<\/a><\/p>\n

Farkas \u00c1, De Laurentiis EI, Schwappach B (2019) The natural history of Get3-like chaperones. Traffic<\/b> 20, 311-324.<\/a><\/p>\n

2018<\/b>
\nMa Y, Ratnasabapathy R, Izzi-Engbeaya C, Nguyen-Tu MS, Richardson E, Hussain S, De Backer I, Holton C, Norton M, Carrat G, Schwappach B, Rutter GA, Dhillo WS, Gardiner J (2018) Hypothalamic arcuate nucleus glucokinase regulates insulin secretion and glucose homeostasis. Diabetes Obes Metab<\/b> 20, 2246-2254.<\/a><\/p>\n

Vitali DG, Sinzel M, Bulthuis EP, Kolb A, Zabel S, Mehlhorn DG, Figueiredo Costa B, Farkas \u00c1, Clancy A, Schuldiner M, Grefen C, Schwappach B, Borgese N, Rapaport D (2018) The GET pathway can increase the risk of mitochondrial outer membrane proteins to be mistargeted to the ER. J Cell Sci<\/b> 131(10):jcs211110<\/a><\/p>\n

Arakel EC, Schwappach B (2018) Correction: Formation of COPI-coated vesicles at a glance (doi:10.1242\/jcs.209890). J Cell Sci<\/b> 131(5):jcs209890.<\/a><\/p>\n

Arakel EC, Schwappach B (2018) Formation of COPI-coated vesicles at a glance. J Cell Sci<\/b> 131(5):jcs209890.<\/a><\/p>\n

Weill U, Arakel EC, Goldmann O, Golan M, Chuartzman S, Munro S, Schwappach B, Schuldiner M (2018) Toolbox: Creating a systematic database of secretory pathway proteins uncovers new cargo for COPI. Traffic<\/b> 19, 370-379.<\/a><\/p>\n

Richter KN, Revelo NH, Seitz KJ, Helm MS, Sarkar D, Saleeb RS, D’Este E, Eberle J, Wagner E, Vogl C, Lazaro DF, Richter F, Coy-Vergara J, Coceano G, Boyden ES, Duncan RR, Hell SW, Lauterbach MA, Lehnart SE, Moser T, Outeiro TF, Rehling P, Schwappach B, Testa I, Zapiec B, Rizzoli SO (2018) Glyoxal as an alternative fixative to formaldehyde in immunostaining and super-resolution microscopy. EMBO J<\/b> 37, 139-159.<\/a><\/p>\n

2017<\/b>
\nArakel EC, Schwappach B (2017) Vesicles: Looking inside the cell Elife<\/b> 6.<\/a><\/p>\n

Geva Y, Crissman J, Arakel EC, G\u00f3mez-Navarro N, Chuartzman SG, Stahmer KR, Schwappach B, Miller EA, Schuldiner M (2017) Two novel effectors of trafficking and maturation of the yeast plasma membrane H+<\/sup> -ATPase. Traffic<\/b> 18, 672-682.<\/a><\/p>\n

2016<\/b>
\nRivera-Monroy J, Musiol L, Unthan-Fechner K, Farkas \u00c1, Clancy A, Coy-Vergara J, Weill U, Gockel S, Lin SY, Corey DP, Kohl T, Str\u00f6bel P, Schuldiner M, Schwappach B, Vilardi F (2016) Mice lacking WRB reveal differential biogenesis requirements of tail-anchored proteins in vivo. Sci Rep<\/b> 6, 39464.<\/a><\/p>\n

Aviram N, Ast T, Costa EA, Arakel EC, Chuartzman SG, Jan CH, Ha\u00dfdenteufel S, Dudek J, Jung M, Schorr S, Zimmermann R, Schwappach B, Weissman JS, Schuldiner M (2016) The SND proteins constitute an alternative targeting route to the endoplasmic reticulum. Nature<\/b> 540, 134-138.<\/a><\/p>\n

Vogl C, Panou I, Yamanbaeva G, Wichmann C, Mangosing SJ, Vilardi F, Indzhykulian AA, Pangr\u0161i\u010d T, Santarelli R, Rodriguez-Ballesteros M, Weber T, Jung S, Cardenas E, Wu X, Wojcik SM, Kwan KY, Del Castillo I, Schwappach B, Strenzke N, Corey DP, Lin SY, Moser T (2016) Tryptophan-rich basic protein (WRB) mediates insertion of the tail-anchored protein otoferlin and is required for hair cell exocytosis and hearing. EMBO J<\/b> 35, 2536-2552.<\/a><\/p>\n

Arakel EC, Richter KP, Clancy A, Schwappach B (2016) \u03b4-COP contains a helix C-terminal to its longin domain key to COPI dynamics and function. Proc Natl Acad Sci U S A<\/b> 113, 6916-6921.<\/a><\/p>\n

Kilisch M, Lytovchenko O, Arakel EC, Bertinetti D, Schwappach B (2016) A dual phosphorylation switch controls 14-3-3-dependent cell surface expression of TASK-1. J Cell Sci<\/b> 129, 831-842.<\/a><\/p>\n

Pfaff J, Rivera Monroy J, Jamieson C, Rajanala K, Vilardi F, Schwappach B, Kehlenbach RH (2016) Emery-Dreifuss muscular dystrophy mutations impair TRC40-mediated targeting of emerin to the inner nuclear membrane. J Cell Sci<\/b> 129, 502-516.<\/a><\/p>\n

Brandenburg S, Arakel EC, Schwappach B, Lehnart SE (2016) The molecular and functional identities of atrial cardiomyocytes in health and disease. Biochim Biophys Acta<\/b> 1863, 1882-1893.<\/a><\/p>\n

2015<\/b>
\nKilisch M, Lytovchenko O, Schwappach B, Renigunta V, Daut J (2015) The role of protein-protein interactions in the intracellular traffic of the potassium channels TASK-1 and TASK-3. Pflugers Arch<\/b> 467, 1105-1120.<\/a><\/p>\n

2014<\/b>
\nVoth W, Schick M, Gates S, Li S, Vilardi F, Gostimskaya I, Southworth DR, Schwappach B, Jakob U (2014) The protein targeting factor Get3 functions as ATP-independent chaperone under oxidative stress conditions. Mol Cell<\/b> 56, 116-127.<\/a><\/p>\n

Elbaz-Alon Y, Morgan B, Clancy A, Amoako TN, Zalckvar E, Dick TP, Schwappach B, Schuldiner M (2014) The yeast oligopeptide transporter Opt2 is localized to peroxisomes and affects glutathione redox homeostasis. FEMS Yeast Res<\/b> 14, 1055-1067.<\/a><\/p>\n

Nussbeck SY, Weil P, Menzel J, Marzec B, Lorberg K, Schwappach B (2014) The laboratory notebook in the 21st century: The electronic laboratory notebook would enhance good scientific practice and increase research productivity. EMBO Rep<\/b> 15, 631-634.<\/a><\/p>\n

Arakel EC, Brandenburg S, Uchida K, Zhang H, Lin YW, Kohl T, Schrul B, Sulkin MS, Efimov IR, Nichols CG, Lehnart SE, Schwappach B (2014) Tuning the electrical properties of the heart by differential trafficking of KATP ion channel complexes. J Cell Sci<\/b> 127, 2106-2119.<\/a><\/p>\n

Vilardi F, Stephan M, Clancy A, Janshoff A, Schwappach B (2014) WRB and CAML are necessary and sufficient to mediate tail-anchored protein targeting to the ER membrane. PLoS One<\/b> 9, e85033.<\/a><\/p>\n

2013<\/b>
\nLeznicki P, Roebuck QP, Wunderley L, Clancy A, Krysztofinska EM, Isaacson RL, Warwicker J, Schwappach B, High S (2013) The association of BAG6 with SGTA and tail-anchored proteins. PLoS One<\/b> 8, e59590.<\/a><\/p>\n

Schuldiner M, Schwappach B (2013) From rags to riches – the history of the endoplasmic reticulum. Biochim Biophys Acta<\/b> 1833, 2389-2391.<\/a><\/p>\n

Powis K, Schrul B, Tienson H, Gostimskaya I, Breker M, High S, Schuldiner M, Jakob U, Schwappach B (2013) Get3 is a holdase chaperone and moves to deposition sites for aggregated proteins when membrane targeting is blocked. J Cell Sci<\/b> 126, 473-483.<\/a><\/p>\n

2012<\/b>
\nWolf W, Kilic A, Schrul B, Lorenz H, Schwappach B, Seedorf M (2012) Yeast Ist2 recruits the endoplasmic reticulum to the plasma membrane and creates a ribosome-free membrane microcompartment. PLoS One<\/b> 7, e39703.<\/a><\/p>\n

2011<\/b>
\nSmith AJ, Daut J, Schwappach B (2011) Membrane proteins as 14-3-3 clients in functional regulation and intracellular transport. Physiology (Bethesda)<\/b> 26, 181-191.<\/a><\/p>\n

2010<\/b>
\nSimpson PJ, Schwappach B, Dohlman HG, Isaacson RL (2010) Structures of Get3, Get4, and Get5 provide new models for TA membrane protein targeting. Structure<\/b> 18, 897-902.<\/a><\/p>\n

Smith AJ, Schwappach B (2010) Cell biology. Think vesicular chloride. Science<\/b> 328, 1364-1365.<\/a><\/p>\n

Braun NA, Morgan B, Dick TP, Schwappach B (2010) The yeast CLC protein counteracts vesicular acidification during iron starvation. J Cell Sci<\/b> 123, 2342-2350.<\/a><\/p>\n

Leznicki P, Clancy A, Schwappach B, High S (2010) Bat3 promotes the membrane integration of tail-anchored proteins. J Cell Sci<\/b> 123, 2170-2178.<\/a><\/p>\n

2009<\/b>
\nRabu C, Schmid V, Schwappach B, High S (2009) Biogenesis of tail-anchored proteins: the beginning for the end? J Cell Sci<\/b> 122, 3605-3612.<\/a><\/p>\n

Jonikas MC, Collins SR, Denic V, Oh E, Quan EM, Schmid V, Weibezahn J, Schwappach B, Walter P, Weissman JS, Schuldiner M (2009) Comprehensive characterization of genes required for protein folding in the endoplasmic reticulum. Science<\/b> 323, 1693-1697.<\/a><\/p>\n

Zuzarte M, Heusser K, Renigunta V, Schlichth\u00f6rl G, Rinn\u00e9 S, Wischmeyer E, Daut J, Schwappach B, Preisig-M\u00fcller R (2009) Intracellular traffic of the K+ channels TASK-1 and TASK-3: role of N- and C-terminal sorting signals and interaction with 14-3-3 proteins. J Physiol<\/b> 587, 929-952.<\/a><\/p>\n

2008<\/b>
\nSchuldiner M, Metz J, Schmid V, Denic V, Rakwalska M, Schmitt HD, Schwappach B, Weissman JS (2008) The GET complex mediates insertion of tail-anchored proteins into the ER membrane. Cell<\/b> 134, 634-645.<\/a><\/p>\n

Favaloro V, Spasic M, Schwappach B, Dobberstein B (2008) Distinct targeting pathways for the membrane insertion of tail-anchored (TA) proteins. J Cell Sci<\/b> 121, 1832-1840.<\/a><\/p>\n

Schwappach B (2008) An overview of trafficking and assembly of neurotransmitter receptors and ion channels (Review). Mol Membr Biol<\/b> 25, 270-278.<\/a><\/p>\n

2007<\/b>
\nMichelsen K, Schmid V, Metz J, Heusser K, Liebel U, Schwede T, Spang A, Schwappach B (2007) Novel cargo-binding site in the beta and delta subunits of coatomer. J Cell Biol<\/b> 179, 209-217.<\/a><\/p>\n

2006<\/b>
\nHeusser K, Yuan H, Neagoe I, Tarasov AI, Ashcroft FM, Schwappach B (2006) Scavenging of 14-3-3 proteins reveals their involvement in the cell-surface transport of ATP-sensitive K+ channels. J Cell Sci<\/b> 119, 4353-4363.<\/a><\/p>\n

Mrowiec T, Schwappach B (2006) 14-3-3 proteins in membrane protein transport. Biol Chem<\/b> 387, 1227-1236.<\/a><\/p>\n

Michelsen K, Mrowiec T, Duderstadt KE, Frey S, Minor DL, Mayer MP, Schwappach B (2006) A multimeric membrane protein reveals 14-3-3 isoform specificity in forward transport in yeast. Traffic<\/b> 7, 903-916.<\/a><\/p>\n

Bundis F, Neagoe I, Schwappach B, Steinmeyer K (2006) Involvement of Golgin-160 in cell surface transport of renal ROMK channel: co-expression of Golgin-160 increases ROMK currents. Cell Physiol Biochem<\/b> 17, 1-12.<\/a><\/p>\n

Renigunta V, Yuan H, Zuzarte M, Rinn\u00e9 S, Koch A, Wischmeyer E, Schlichth\u00f6rl G, Gao Y, Karschin A, Jacob R, Schwappach B, Daut J, Preisig-M\u00fcller R (2006) The retention factor p11 confers an endoplasmic reticulum-localization signal to the potassium channel TASK-1. Traffic<\/b> 7, 168-181.<\/a><\/p>\n

Metz J, W\u00e4chter A, Schmidt B, Bujnicki JM, Schwappach B (2006) The yeast Arr4p ATPase binds the chloride transporter Gef1p when copper is available in the cytosol. J Biol Chem<\/b> 281, 410-417.<\/a><\/p>\n

2005<\/b>
\nMichelsen K, Yuan H, Schwappach B (2005) Hide and run. Arginine-based endoplasmic-reticulum-sorting motifs in the assembly of heteromultimeric membrane proteins. EMBO Rep<\/b> 6, 717-722.<\/a><\/p>\n

Heusser K, Schwappach B (2005) Trafficking of potassium channels. Curr Opin Neurobiol<\/b> 15, 364-369.<\/a><\/p>\n

J\u00fcschke C, W\u00e4chter A, Schwappach B, Seedorf M (2005) SEC18\/NSF-independent, protein-sorting pathway from the yeast cortical ER to the plasma membrane. J Cell Biol<\/b> 169, 613-622.<\/a><\/p>\n

Neagoe I, Schwappach B (2005) Pas de deux in groups of four–the biogenesis of KATP channels. J Mol Cell Cardiol<\/b> 38, 887-894.<\/a><\/p>\n

W\u00e4chter A, Schwappach B (2005) The yeast CLC chloride channel is proteolytically processed by the furin-like protease Kex2p in the first extracellular loop. FEBS Lett<\/b> 579, 1149-1153.<\/a><\/p>\n

Stegmayer C, Kehlenbach A, Tournaviti S, Wegehingel S, Zehe C, Denny P, Smith DF, Schwappach B, Nickel W (2005) Direct transport across the plasma membrane of mammalian cells of Leishmania HASPB as revealed by a CHO export mutant. J Cell Sci<\/b> 118, 517-527.<\/a><\/p>\n

2004<\/b>
\nBackhaus R, Zehe C, Wegehingel S, Kehlenbach A, Schwappach B, Nickel W (2004) Unconventional protein secretion: membrane translocation of FGF-2 does not require protein unfolding. J Cell Sci<\/b> 117, 1727-1736.<\/a><\/p>\n

2003<\/b>
\nYuan H, Michelsen K, Schwappach B (2003) 14-3-3 dimers probe the assembly status of multimeric membrane proteins. Curr Biol<\/b> 13, 638-646.<\/a><\/p>\n<\/div><\/div><\/div><\/div><\/div><\/div>\n","protected":false},"excerpt":{"rendered":"","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"footnotes":""},"folder":[85],"class_list":["post-4885","page","type-page","status-publish","hentry"],"acf":[],"_links":{"self":[{"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/pages\/4885","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/comments?post=4885"}],"version-history":[{"count":14,"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/pages\/4885\/revisions"}],"predecessor-version":[{"id":8328,"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/pages\/4885\/revisions\/8328"}],"wp:attachment":[{"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/media?parent=4885"}],"wp:term":[{"taxonomy":"folder","embeddable":true,"href":"https:\/\/biochemie.uni-goettingen.de\/index.php\/wp-json\/wp\/v2\/folder?post=4885"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}