Generation of Lasso Peptide-Based ClpP Binders

The Clp protease system fulfills a plethora of important functions in bacteria. It consists of a tetradecameric ClpP barrel holding the proteolytic centers and two hexameric Clp-ATPase rings, which recognize, unfold, and then feed substrate proteins into the ClpP barrel for proteolytic degradation. Flexible loops carrying conserved tripeptide motifs protrude from the Clp-ATPases and bind into hydrophobic pockets (H-pockets) on ClpP. Here, we set out to engineer microcin J25 (MccJ25), a ribosomally synthesized and post-translationally modified peptide (RiPP) of the lasso peptide subfamily, by introducing the conserved tripeptide motifs into the lasso peptide loop region to mimic the Clp-ATPase loops. We studied the capacity of the resulting lasso peptide variants to bind to ClpP and affect its activity. From the nine variants generated, one in particular (12IGF) was able to activate ClpP from Staphylococcus aureus and Bacillus subtilis. While 12IGF conferred stability to ClpP tetradecamers and stimulated peptide degradation, it did not trigger unregulated protein degradation, in contrast to the H-pocket-binding acyldepsipeptide antibiotics (ADEPs). Interestingly, synergistic interactions between 12IGF and ADEP were observed.

Cellulonodin-2 and Lihuanodin: Lasso Peptides with an Aspartimide Post-Translational Modification

Lasso peptides are a family of ribosomally synthesized and post-translationally modified peptides (RiPPs) defined by their threaded structure. Besides the class-defining isopeptide bond, other post-translational modifications (PTMs) that further tailor lasso peptides have been previously reported. Using genome mining tools, we identified a subset of lasso peptide biosynthetic gene clusters (BGCs) that are colocalized with protein L-isoaspartyl methyltransferase (PIMT) homologs. PIMTs have an important role in protein repair, restoring isoaspartate residues formed from asparagine deamidation to aspartate. Here we report a new function for PIMT enzymes in the post-translational modification of lasso peptides. The PIMTs associated with lasso peptide BGCs first methylate an L-aspartate sidechain found within the ring of the lasso peptide. The methyl ester is then converted into a stable aspartimide moiety, endowing the lasso peptide ring with rigidity relative to its unmodified counterpart. We describe the heterologous expression and structural characterization of two examples of aspartimide-modified lasso peptides from thermophilic Gram-positive bacteria. The lasso peptide cellulonodin-2 is encoded in the genome of actinobacterium Thermobifida cellulosilytica, while lihuanodin is encoded in the genome of firmicute Lihuaxuella thermophila. Additional genome mining revealed PIMT-containing lasso peptide BGCs in 48 organisms. In addition to heterologous expression, we have reconstituted PIMT-mediated aspartimide formation in vitro, showing that lasso peptide-associated PIMTs transfer methyl groups very rapidly as compared to canonical PIMTs. Furthermore, in stark contrast to other characterized lasso peptide PTMs, the methyltransferase functions only on lassoed substrates.

Discovery of the Class I Antimicrobial Lasso Peptide Arcumycin

<p>Lasso peptides are a structurally diverse superfamily of</p><p>conformationally-constrained peptide natural products, of which a</p><p>subset exhibits broad antimicrobial activity. Although advances in</p><p>bioinformatics have increased our knowledge of strains harboring</p><p>the biosynthetic machinery for lasso peptide production, relating</p><p>peptide sequence to bioactivity remains a continuous challenge.</p><p>Towards this end, a structure-driven genome mining investigation</p><p>of Actinobacteria-produced antimicrobial lasso peptides was</p><p>performed to correlate predicted primary structure with antibiotic</p><p>activity. Bioinformatic evaluation revealed eight putative novel</p><p>class I lasso peptide sequences. This subset is predicted to</p><p>possess antibiotic activity as characterized members of this class</p><p>have both broad spectrum and potent activity against Gram positive</p><p>strains. Fermentation of one of these hits, Streptomyces</p><p>NRRL F-5639, resulted in the production of a novel class I lasso</p><p>peptide, arcumycin, named for the Latin word for bow or arch,</p><p>arcum. Arcumycin exhibited antibiotic activity against Gram positive</p><p>bacteria including <i>Bacillus subtilis</i> (4 μg/mL),</p><p><i>Staphylococcus aureus </i>(8 μg/mL), and <i>Micrococcus luteus</i> (8</p><p>μg/mL). Arcumycin treatment of <i>B. subtilis</i> liaI-β-gal promoter</p><p>fusion reporter strain resulted in upregulation of the system liaRS</p><p>by the promoter liaI, indicating arcumycin interferes with lipid II</p><p>biosynthesis. Cumulatively, the results illustrate the relationship</p><p>between phylogenetically related lasso peptides and their</p><p>bioactivity as validated through the isolation, structural</p><p>determination, and evaluation of bioactivity of the novel class I</p><p>antimicrobial lasso peptide arcumycin.</p>

Discovery of the Class I Antimicrobial Lasso Peptide Arcumycin

<p>Lasso peptides are a structurally diverse superfamily of</p><p>conformationally-constrained peptide natural products, of which a</p><p>subset exhibits broad antimicrobial activity. Although advances in</p><p>bioinformatics have increased our knowledge of strains harboring</p><p>the biosynthetic machinery for lasso peptide production, relating</p><p>peptide sequence to bioactivity remains a continuous challenge.</p><p>Towards this end, a structure-driven genome mining investigation</p><p>of Actinobacteria-produced antimicrobial lasso peptides was</p><p>performed to correlate predicted primary structure with antibiotic</p><p>activity. Bioinformatic evaluation revealed eight putative novel</p><p>class I lasso peptide sequences. This subset is predicted to</p><p>possess antibiotic activity as characterized members of this class</p><p>have both broad spectrum and potent activity against Gram positive</p><p>strains. Fermentation of one of these hits, Streptomyces</p><p>NRRL F-5639, resulted in the production of a novel class I lasso</p><p>peptide, arcumycin, named for the Latin word for bow or arch,</p><p>arcum. Arcumycin exhibited antibiotic activity against Gram positive</p><p>bacteria including <i>Bacillus subtilis</i> (4 μg/mL),</p><p><i>Staphylococcus aureus </i>(8 μg/mL), and <i>Micrococcus luteus</i> (8</p><p>μg/mL). Arcumycin treatment of <i>B. subtilis</i> liaI-β-gal promoter</p><p>fusion reporter strain resulted in upregulation of the system liaRS</p><p>by the promoter liaI, indicating arcumycin interferes with lipid II</p><p>biosynthesis. Cumulatively, the results illustrate the relationship</p><p>between phylogenetically related lasso peptides and their</p><p>bioactivity as validated through the isolation, structural</p><p>determination, and evaluation of bioactivity of the novel class I</p><p>antimicrobial lasso peptide arcumycin.</p>