Supporting data for <i>“</i>Metabolic Engineering of 'Last Line Antibiotic' Colistin in <i>Paenibacillus polymyxa</i><i>”</i>

<p dir="ltr">Colistin, also known as polymyxin E, is an antibiotic considered as last-line treatment for infections caused by multidrug-resistant gram-negative bacteria. The clinical application of colistin has high standards on its analog ratio and purity, which poses a high challenge to its production and downstream isolation process. Recently, with the advances in synthetic biology techniques, rational metabolic engineering of colistin natural producers is becoming a promising strategy to address this challenge.</p><p dir="ltr">This study aimed to perform rational metabolic engineering for colistin production in <i>Paenibacillus polymyxa </i>ATCC 842 to construct an ideal host for the efficient production of colistin with a clean background.</p><p dir="ltr">In the first section, we analyzed the colistin analogs produced by colistin natural<i> </i>producer strain <i>P</i><i>.</i><i> polymyxa</i> ATCC 842 and inactivated its non-essential BGCs. The primary colistin analogs produced by <i>P</i><i>.</i><i> polymyxa</i> ATCC 842 were identified as colistin A and colistin B, and the ratio of the analogs complies with the British Pharmacopoeia and European Pharmacopoeia standards for pharmaceutical colistin. Subsequently, by respective inactivation of 8 non-essential biosynthetic gene clusters (BGCs) via CRISPR/Cas9-based gene editing in the chassis strain, we found that the mutant P3 with inactivation of BGC 4, an NRPS-PKS BGC, could dramatically improve secondary metabolites production, which increased the colistin titer by 79% to 315.4mg/L. Additionally, through multiple inactivation of 7 non-essential BGCs, an engineered strain P14 with a clean metabolic background was generated.</p><p dir="ltr">In the second section, we further improved the chassis strain's colistin titer by strengthening the precursor supply. Nine promoters in <i>P</i><i>.</i><i> polymyxa</i> ATCC 842 were characterized, and the promoter P_H4 was applied to strengthen the expression of the genes involved in the L-2,4-DABA pathway. By co-overexpression of diaminobutyrate-2-oxoglutarate transaminase <i>ectB</i> and aspartate kinase <i>lysC</i>, an engineered strain P19 with a 649.3 mg/L colistin titer, which was 269% higher than the starting strain, was obtained. Finally, in 5 L bioreactor continuous fermentation, the final colistin titer achieved 1711.7 mg/L.</p><p dir="ltr">This study represents the pioneering case of metabolic engineering for colistin production in <i>P. polymyxa</i>, its natural producer. We successfully developed an engineered strain, P19, with high colistin production and a clean metabolite background. These findings hold promising implications for advancing the metabolic engineering of NRPS products in non-model Bacillota strains.</p>