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Structural basis for (p)ppGpp synthesis by the Staphylococcus aureus small alarmone synthetase RelP

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  • Melek Cemre Manav
  • Jelena Beljantseva, University of Tartu, Estonia, Estonia
  • Martin Saxtorph Bojer, University of Copenhagen, Denmark
  • Tanel Tenson, University of Tartu, Estonia, Estonia
  • Hanne Ingmer, University of Copenhagen, Denmark
  • Vasili Hauryliuk, Umeå University, Sweden
  • Ditlev Egeskov Brodersen

The stringent response is a global reprogramming of bacterial physiology that renders cells more tolerant to antibiotics and induces virulence gene expression in pathogens in response to stress. This process is driven by accumulation of the intracellular alarmone guanosine-5'-di(tri)phosphate-3'-diphosphate ([p]ppGpp), which is produced by enzymes of the RelA SpoT homologue (RSH) family. The Gram-positive Firmicute pathogen, Staphylococcus aureus, encodes three RSH enzymes: a multi-domain RSH (Rel) that senses amino acid starvation on the ribosome and two small alarmone synthetase (SAS) enzymes, RelQ (SAS1) and RelP (SAS2). In Bacillus subtilis, RelQ (SAS1) was shown to form a tetramer that is activated by pppGpp and inhibited by single stranded RNA, but the structural and functional regulation of RelP (SAS2) is unexplored. Here, we present crystal structures of S. aureus RelP in two major functional states, pre-catalytic (bound to GTP and the non-hydrolyzable ATP analogue, AMPCPP) and post-catalytic (bound to pppGpp). We observed that RelP also forms a tetramer, but unlike RelQ (SAS1), it is strongly inhibited by both pppGpp and ppGpp and is insensitive to inhibition by RNA. We also identified putative metal ion-binding sites at the subunit interfaces that were consistent with the observed activation of the enzyme by Zn2+ ions. The structures reported here reveal the details of the catalytic mechanism of SAS enzymes and provide a molecular basis for understanding differential regulation of SAS enzymes in Firmicute bacteria.

Original languageEnglish
JournalJournal of Biological Chemistry
Pages (from-to)3254-3264
Number of pages11
Publication statusPublished - 2018

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  • Journal Article

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