Guanidinoacetic acid, as an energetic substance, has a wide range of applications in the food, pharmaceutical, and feed industries. However, the biosynthesis of guanidinoacetic acid has not been applied in industrial production. In this study, we designed the synthetic route of guanidinoacetic acid in a food-grade strain of Bacillus subtilis. By regulating the expression of key enzymes, lifting feedback inhibition, and increasing membrane permeability, we achieved the efficient synthesis of guanidinoacetic acid by whole-cell catalysis. Firstly, the optimal L-arginine:glycine amidinotransferase was screened based on the phylogenetic tree, and the expression of the key enzyme was enhanced by a strategy combining strong promoter and genome integration. Secondly, the ornithine cycle for L-arginine synthesis in Corynebacterium glutamicum was introduced to alleviate the feedback inhibition of the enzyme by the byproduct L-ornithine, and the L-arginine degradation pathway was knocked down to enhance substrate regeneration. Thirdly, the expression of N-acetylmuramoyl-L-alanine amidase (LytC) was up-regulated to increase the cell membrane permeability. Finally, after optimization of whole-cell production conditions, strain Bs-13 achieved guanidinoacetic acid production at a titer of 13.1 g/L after 24 h, with a proudction rate of 0.54 g/(L·h) and a glycine conversion rate of 92.7%. The above strategy improved the production of guanidinoacetic acid and provided a reference for the biosynthesis of guanidinoacetic acid.