<p><Emphasis Type="Underline">B</Emphasis>acterial <Emphasis Type="Underline">p</Emphasis>roteasomal <Emphasis Type="Underline">a</Emphasis>ctivator (Bpa) is a regulatory particle of the <i>Mycobacterium tuberculosis</i> proteasome that facilitates the recruitment of substrates and their subsequent degradation by the 20S core particle. Substrate-bound structures of Bpa are unavailable, leaving its recruitment mechanism incompletely understood. Here, we use mass spectrometry and NMR to show that Bpa reversibly assembles into dodecamers from dimers/tetramers in a temperature-dependent manner in vitro, and map the oligomerization interfaces during assembly. To overcome the limitations posed by the poor solubility of natural Bpa substrates, we establish the DNA-binding domain of hTRF1 as a model substrate. We quantify the affinity and stoichiometry of the Bpa-hTRF1 interaction using methyl-TROSY NMR, identifying a 12 Bpa subunit: 3 hTRF1 binding ratio with micromolar affinity that is modulated by salt concentration. Our work maps the Bpa-hTRF1 interface at atomic resolution, identifies determinants of substrate engagement, and introduces a tractable substrate for dissecting proteasomal recognition in mycobacteria.</p>

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Structural heterogeneity and substrate engagement mechanism of the bacterial proteasome activator Bpa

  • Bradley T. V. Davis,
  • Enrico Rennella,
  • Anisha Haris,
  • Jakub Ujma,
  • David Bruton,
  • Keith Richardson,
  • Kevin Giles,
  • Lewis E. Kay,
  • Siavash Vahidi

摘要

Bacterial proteasomal activator (Bpa) is a regulatory particle of the Mycobacterium tuberculosis proteasome that facilitates the recruitment of substrates and their subsequent degradation by the 20S core particle. Substrate-bound structures of Bpa are unavailable, leaving its recruitment mechanism incompletely understood. Here, we use mass spectrometry and NMR to show that Bpa reversibly assembles into dodecamers from dimers/tetramers in a temperature-dependent manner in vitro, and map the oligomerization interfaces during assembly. To overcome the limitations posed by the poor solubility of natural Bpa substrates, we establish the DNA-binding domain of hTRF1 as a model substrate. We quantify the affinity and stoichiometry of the Bpa-hTRF1 interaction using methyl-TROSY NMR, identifying a 12 Bpa subunit: 3 hTRF1 binding ratio with micromolar affinity that is modulated by salt concentration. Our work maps the Bpa-hTRF1 interface at atomic resolution, identifies determinants of substrate engagement, and introduces a tractable substrate for dissecting proteasomal recognition in mycobacteria.