bims-polyam Biomed News
on Polyamines
Issue of 2021‒03‒21
two papers selected by
Sebastian J. Hofer
University of Graz
  1. Polyamine Transport Assay Using Reconstituted Yeast Membranes.
  2. Natural combinatorial genetics and prolific polyamine production enable siderophore diversification in Serratia plymuthica.
  1. Bio Protoc. 2021 Jan 20. 11(2): e3888
    Polyamine Transport Assay Using Reconstituted Yeast Membranes.
    Sarah Van Veen, Shaun Martin, Marleen Schuermans, Peter Vangheluwe.
      ATP13A2/PARK9 is a late endo-/lysosomal P5B transport ATPase that is associated with several neurodegenerative disorders. We recently characterized ATP13A2 as a lysosomal polyamine exporter, which sheds light on the molecular identity of the unknown mammalian polyamine transport system. Here, we describe step by step a protocol to measure radiolabeled polyamine transport in reconstituted vesicles from yeast cells overexpressing human ATP13A2. This protocol was developed as part of our recent publication (van Veen et al., 2020 ) and will be useful for characterizing the transport function of other putative polyamine transporters, such as isoforms of the P5B transport ATPases.
    Keywords:  ATP13A2; P5 ATPase; Polyamine; Reconstitution; Spermine; Transport assay; Yeast membranes
    DOI:  https://doi.org/10.21769/BioProtoc.3888
  2. BMC Biol. 2021 Mar 15. 19(1): 46
    Natural combinatorial genetics and prolific polyamine production enable siderophore diversification in Serratia plymuthica.
    Sara Cleto, Kristina Haslinger, Kristala L J Prather, Timothy K Lu.
      BACKGROUND: Iron is essential for bacterial survival. Bacterial siderophores are small molecules with unmatched capacity to scavenge iron from proteins and the extracellular milieu, where it mostly occurs as insoluble Fe3+. Siderophores chelate Fe3+ for uptake into the cell, where it is reduced to soluble Fe2+. Siderophores are key molecules in low soluble iron conditions. The ability of bacteria to synthesize proprietary siderophores may have increased bacterial evolutionary fitness; one way that bacteria diversify siderophore structure is by incorporating different polyamine backbones while maintaining the catechol moieties.RESULTS: We report that Serratia plymuthica V4 produces a variety of siderophores, which we term the siderome, and which are assembled by the concerted action of enzymes encoded in two independent gene clusters. Besides assembling serratiochelin A and B with diaminopropane, S. plymuthica utilizes putrescine and the same set of enzymes to assemble photobactin, a siderophore found in the bacterium Photorhabdus luminescens. The enzymes encoded by one of the gene clusters can independently assemble enterobactin. A third, independent operon is responsible for biosynthesis of the hydroxamate siderophore aerobactin, initially described in Enterobacter aerogenes. Mutant strains not synthesizing polyamine-siderophores significantly increased enterobactin production levels, though lack of enterobactin did not impact the production of serratiochelins. Knocking out SchF0, an enzyme involved in the assembly of enterobactin alone, significantly reduced bacterial fitness.
    CONCLUSIONS: This study shows the natural occurrence of serratiochelins, photobactin, enterobactin, and aerobactin in a single bacterial species and illuminates the interplay between siderophore biosynthetic pathways and polyamine production, indicating routes of molecular diversification. Given its natural yields of diaminopropane (97.75 μmol/g DW) and putrescine (30.83 μmol/g DW), S. plymuthica can be exploited for the industrial production of these compounds.
    Keywords:  Natural products; Pathway elucidation; Polyamines; Siderophores
    DOI:  https://doi.org/10.1186/s12915-021-00971-z
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