<p>Heme, an iron-incorporated porphyrin compound, serves as the prosthetic group for numerous proteins involved in diverse biological processes. The prokaryotic heme biosynthetic pathway features a complex cascade of reactions, in which glutamyl-tRNA reductase (GluTR) catalyzes the formation of 5-aminolevulinic acid (ALA) that represents a critical rate-limiting step and determines ultimate heme yield. In this study, OsGluTR<sup>A510V</sup> showed enhanced heme synthesis capacity in <i>Oryza sativa</i> and was used for developing microbial cell factories dedicated to free heme production. Through systematic protein engineering involving site-directed mutagenesis and <i>N</i>-terminal modification, OsGluTR<sup>A510V</sup> was optimized to improve the structural stability and catalytic efficiency. It yielded the recombinant enzyme GluTR<sup>A510V/S189T/KK</sup>, which achieved a maximum heme titer of 13.14&#xa0;mg/L in <i>Escherichia coli</i>, representing a 7.6-fold improvement over that of GluTR<sup>A510V</sup>. To establish heme production in <i>Bacillus subtilis</i>, GluTR<sup>A510V/S189T/KK</sup> was introduced into the ΔhmoAB-hemX chassis, a modified <i>B. subtilis</i> host lacking key heme biosynthesis inhibitors (<i>hmoA</i>, <i>hmoB</i>, and <i>hemX</i>). This engineered system elevated the heme yield from 0.77 to 3.86&#xa0;mg/L, achieving a 5.0-fold improvement. This study demonstrates a combinatory metabolic engineering strategy that reconstitutes the heme synthetic route in <i>B. subtilis</i>, enabling efficient production of food-grade free heme through enzyme engineering and chassis optimization.</p>

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Metabolic engineering of Bacillus subtilis for enhanced free heme biosynthesis by an enzyme-chassis co-optimization strategy

  • Shuoqi Diao,
  • Haoqiang Zhou,
  • Yang Li,
  • Jingcheng Dai,
  • Dazhong Yan,
  • Jing Wu

摘要

Heme, an iron-incorporated porphyrin compound, serves as the prosthetic group for numerous proteins involved in diverse biological processes. The prokaryotic heme biosynthetic pathway features a complex cascade of reactions, in which glutamyl-tRNA reductase (GluTR) catalyzes the formation of 5-aminolevulinic acid (ALA) that represents a critical rate-limiting step and determines ultimate heme yield. In this study, OsGluTRA510V showed enhanced heme synthesis capacity in Oryza sativa and was used for developing microbial cell factories dedicated to free heme production. Through systematic protein engineering involving site-directed mutagenesis and N-terminal modification, OsGluTRA510V was optimized to improve the structural stability and catalytic efficiency. It yielded the recombinant enzyme GluTRA510V/S189T/KK, which achieved a maximum heme titer of 13.14 mg/L in Escherichia coli, representing a 7.6-fold improvement over that of GluTRA510V. To establish heme production in Bacillus subtilis, GluTRA510V/S189T/KK was introduced into the ΔhmoAB-hemX chassis, a modified B. subtilis host lacking key heme biosynthesis inhibitors (hmoA, hmoB, and hemX). This engineered system elevated the heme yield from 0.77 to 3.86 mg/L, achieving a 5.0-fold improvement. This study demonstrates a combinatory metabolic engineering strategy that reconstitutes the heme synthetic route in B. subtilis, enabling efficient production of food-grade free heme through enzyme engineering and chassis optimization.