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. 2023 Jul;107(13):4245-4260.
doi: 10.1007/s00253-023-12592-3. Epub 2023 May 29.

Formamide-based production of amines by metabolically engineering Corynebacterium glutamicum

Lynn S Schwardmann  1 Tong Wu  2 Aron K Dransfeld  1 Steffen N Lindner  2 Volker F Wendisch  3
Affiliations

Formamide-based production of amines by metabolically engineering Corynebacterium glutamicum

Lynn S Schwardmann et al. Appl Microbiol Biotechnol. 2023 Jul.

Abstract

Formamide is rarely used as nitrogen source by microorganisms. Therefore, formamide and formamidase have been used as protection system to allow for growth under non-sterile conditions and for non-sterile production of acetoin, a product lacking nitrogen. Here, we equipped Corynebacterium glutamicum, a renowned workhorse for industrial amino acid production for 60 years, with formamidase from Helicobacter pylori 26695, enabling growth with formamide as sole nitrogen source. Thereupon, the formamide/formamidase system was exploited for efficient formamide-based production of the nitrogenous compounds L-glutamate, L-lysine, N-methylphenylalanine, and dipicolinic acid by transfer of the formamide/formamidase system to established producer strains. Stable isotope labeling verified the incorporation of nitrogen from formamide into biomass and the representative product L-lysine. Moreover, we showed ammonium leakage during formamidase-based access of formamide to be exploitable to support growth of formamidase-deficient C. glutamicum in co-cultivation and demonstrated that efficient utilization of formamide as sole nitrogen source benefitted from overexpression of formate dehydrogenase. KEY POINTS: • C. glutamicum was engineered to access formamide. • Formamide-based production of nitrogenous compounds was established. • Nitrogen cross-feeding supported growth of a formamidase-negative strain.

Keywords: Amine production; Co-cultivation; Corynebacterium glutamicum; Formamidase; Formamide.

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Conflict of interest statement

The authors declare no competing interests.

Figures

Fig. 1
Fig. 1
Influence of formamide and formate on the growth of C. glutamicum strains. Biomass (dark blue circles), µmax (light blue triangles), and lag phase (purple squares) of strains WT-EV (open symbols) and FORM (closed symbols), cultivated in CgXII minimal medium (a, b, d, e) or N-CgXII (c) supplemented with 40 g L−1 glucose and either 0–160 mM formamide (a, b, c) or 0–160 mM sodium formate (d, e) in a BioLector microcultivation system for 96 h. Values represent means with standard deviations of triplicate cultivations
Fig. 2
Fig. 2
AmiF activity in crude extracts (a), 15N labeling of L-lysine from 15N-labeled formamide (b), and growth (c) of formamidase-expressing strain FORM (blue) and WT-EV (grey) with formamide as sole nitrogen source. Cells were grown in LB over night for crude extract preparation (a). Cells were grown in CgXII minimal medium containing 468 mM unlabeled (14N) N in form of urea and (NH4)2SO4, supplemented with 60 mM 15N labeled formamide (15N) and 40 g L−1 glucose, in a BioLector microcultivation system for 24 h. The patterns depict the fractions of 0 (grey), 1 (red), or 2 (purple) labeled nitrogen atoms per molecule of lysine in the biomass. Standard deviations refer to triplicate cultivations. For growth assessment, cells were grown in N-CgXII minimal medium, supplemented with 40 mM formamide for 28 h (c). Values represent means with standard deviations of triplicate measurements or cultivations. *n.d., not detectable (< 0.4 U mg.−1)
Fig. 3
Fig. 3
15N labeling of L-lysine, L-alanine, L-serine, L-proline, and L-tyrosine in strain FORM. Cells were grown in N-CgXII, supplemented with 60 mM 15N-labeled (NH4)2SO4 or formamide and 40 g L−1 glucose, in a BioLector microcultivation system for 24 h. The patterns depict the fractions of 0 (grey), 1 (red), or 2 (purple) labeled nitrogen atoms per molecule of lysine in the biomass. Standard deviations refer to triplicate cultivations
Fig. 4
Fig. 4
15N labeling of lysine in WT-EV and FORM from 15N-labeled ammonium sulfate or formamide. Cells were grown in N-CgXII, supplemented with 60 mM unlabeled (114N) or labeled (15N) (NH4)2SO4 or formamide (a), or with 30 mM labeled or unlabeled (NH4)2SO4 and formamide, respectively (b), and 40 g L−1 glucose, in a BioLector microcultivation system for 24 h. The patterns depict the fractions of 0 (grey), 1 (red), or 2 (purple) labeled nitrogen atoms per molecule of lysine in the biomass. Standard deviations refer to triplicate cultivations. *n.g., no growth with formamide
Fig. 5
Fig. 5
Free ammonium in supernatants of cells of WT-crimson (a) and FORM-gfp (b). Cells were either grown separately (a, b) or in co-culture inoculated with 70% WT-crimson and 30% FORM-gfp (c), supplemented with 60 mM N in form of urea and (NH4)2SO4 (grey) or with 60 mM formamide (blue) and 40 g L−1 glucose as carbon source, for 24 h. Values represent means of triplicate measurements with standard deviations. *n.g., no growth with formamide
Fig. 6
Fig. 6
Co-cultures of strains WT-crimson (red) and FORM-gfp (green) in varied inoculum ratios. To test if FORM-gfp can provide nitrogen from formamide for growth of amiF-deficient WT-crimson, cells were grown with 60 mM formamide as sole nitrogen source in N-CgXII, whereas a control cultivation in CgXII minimal medium supplemented with 60 mM N in form of urea and (NH4)2SO4 was also made (grey background). 40 g L-1 glucose was added as carbon source. The inoculum contained the indicated percentage of FORM-gfp with the rest to 100% being WT-crimson cells. Biomass formation (black diamond) and culture compositions (stacked red and green bars) were determined after 0, 8, and 24 h by OD600 and FACS analysis. Values represent means with standard deviations of triplicate cultivations
Fig. 7
Fig. 7
Biomass formation (a), maximal growth rates µmax (b), and lag phases (c) of FORM (blue) and formate dehydrogenase overexpressing strains FORM-FdhCg (green) and FORM-FdhPs (orange). Strains were cultivated in N-CgXII, supplemented with 40 g L−1 glucose and 60, 120, or 160 mM formamide in a BioLector microcultivation system for 96 h. Values represent means with standard deviations of triplicate cultivations
Fig. 8
Fig. 8
15N labelling of lysine in biomass and supernatants of strains Lys and Lys-FORM. Cells were grown in N-CgXII, supplemented with 60 mM unlabeled (14N) or labeled (15N) (NH4)2SO4 or formamide, using 40 g L−1 glucose, in a BioLector microcultivation system for 24 h. The patterns depict the fractions of 0 (grey), 1 (red), or 2 (purple) of labeled nitrogen atoms per molecule of lysine in the biomass (filled bars) or the supernatant (dashed bars). Values represent means with standard deviations of triplicate cultivations. *n.g., no growth with formamide
Fig. 9
Fig. 9
Biomass formation (a), maximal growth rates µmax (b), lag phases (c), and L-lysine titers (d) for strains Lys-FORM (blue), Fdh-overexpressing Lys-FORM-FdhPs (orange), and Lys-FORM-FdhCg (green). Strains were cultivated in N-CgXII, supplemented with 60 or 120 mM nitrogen in form of urea and (NH4)2SO4 (filled bars) or formamide (dashed bars) and 40 g L−1 glucose, in a BioLector microcultivation system for 96 h. Values represent means with standard deviations of triplicate cultivations
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