Abstract
INTRODUCTION: β-nicotinamide mononucleotide (NMN), a precursor of NAD(+), holds promise as a functional food ingredient for mitigating age-related decline. This study enhanced NMN biosynthesis in probiotic Lactiplantibacillus plantarum. METHODS: A putative niacin transporter, lp2514, was identified via molecular docking and validated by CRISPR/Cas9. A dual-copy expression strategy was also employed to increase NMN production. In parallel, RNA-seq was used to analyze genome-wide transcriptional changes associated with enhanced NMN biosynthesis. RESULTS: Overexpression of lp2514 increased NMN production by 62.3%, and a dual-copy strategy raised NMN titers to 203 μmol L(-1)-269% increase compared to empty-vector control without NAM and the highest yield reported in lactic acid bacteria. Transcriptomic analysis revealed 598 differentially expressed genes, including upregulated ribosomal proteins (rpsJ, rplE) and NAD(+) salvage enzymes (aspA), indicating enhanced translation and precursor flux. Deleting cinA, encoding a metabolic constraint, further boosted NMN levels, confirming transcriptomic predictions. DISCUSSION: This combined transporter engineering and transcriptome-guided strategy establishes a food-grade L. plantarum platform for efficient NMN production in functional fermented foods.