<p>Peroxiredoxins are thiol peroxidases, which detoxify peroxides, relay redox signals and act as chaperones. In eukaryotes, multiple peroxiredoxin-1 (Prx1)/AhpC-type isoforms frequently co-exist in the same subcellular compartment, yet have been assumed to assemble only as homo-oligomeric complexes. Here we show that hetero-oligomerization is a conserved and functionally relevant property of Prx1/AhpC-type peroxiredoxins. Using biochemical reconstitution, native mass photometry, electron microscopy and live-cell assays, we demonstrate formation of heterodimers and heterodecamers, with diverse subunit stoichiometries, in peroxiredoxin pairs from different eukaryotic kingdoms. In <i>Saccharomyces cerevisiae</i>, oxidative challenge induces Tsa1–Tsa2 heterodecamerization with substoichiometric Tsa2 incorporation sufficing to stabilize the decameric state. Functional hetero-oligomers are also observed forming among human, plant and <i>Leishmania</i> peroxiredoxins. Our findings provide new insights into peroxiredoxin structural plasticity with broad implications for redox biology, stress responses and cellular adaptation, and also challenge the long-held paradigm of peroxiredoxin homo-oligomerization.</p><p></p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Hetero-oligomerization drives structural plasticity of eukaryotic peroxiredoxins

  • Jannik Zimmermann,
  • Lukas Lang,
  • Julia Malo Pueyo,
  • Mareike Riedel,
  • Khadija Wahni,
  • Dylan Stobbe,
  • Laura Leiskau,
  • Elham Aref,
  • Christopher Lux,
  • Steven Janvier,
  • Didier Vertommen,
  • Svenja Lenhard,
  • Frank Hannemann,
  • Sudharshini Thangamuragan,
  • Helena Castro,
  • Volkhard Helms,
  • Ana Maria Tomas,
  • Johannes M. Herrmann,
  • Armindo Salvador,
  • Timo Mühlhaus,
  • Jan Riemer,
  • Joris Messens,
  • Marcel Deponte,
  • Bruce Morgan

摘要

Peroxiredoxins are thiol peroxidases, which detoxify peroxides, relay redox signals and act as chaperones. In eukaryotes, multiple peroxiredoxin-1 (Prx1)/AhpC-type isoforms frequently co-exist in the same subcellular compartment, yet have been assumed to assemble only as homo-oligomeric complexes. Here we show that hetero-oligomerization is a conserved and functionally relevant property of Prx1/AhpC-type peroxiredoxins. Using biochemical reconstitution, native mass photometry, electron microscopy and live-cell assays, we demonstrate formation of heterodimers and heterodecamers, with diverse subunit stoichiometries, in peroxiredoxin pairs from different eukaryotic kingdoms. In Saccharomyces cerevisiae, oxidative challenge induces Tsa1–Tsa2 heterodecamerization with substoichiometric Tsa2 incorporation sufficing to stabilize the decameric state. Functional hetero-oligomers are also observed forming among human, plant and Leishmania peroxiredoxins. Our findings provide new insights into peroxiredoxin structural plasticity with broad implications for redox biology, stress responses and cellular adaptation, and also challenge the long-held paradigm of peroxiredoxin homo-oligomerization.