Using antibiotics has a great impact on the treatment of bacterial infections. However, the emergence of multi-drug resistant bacteria requires new antibacterial targets and drugs. Bacteria are surrounded by the netlike polymer peptidoglycan, which is responsible for a defined cell shape and allows bacteria to live in a variable internal osmotic environment. Among the several enzymes involved in cell-wall biosynthesis, transglycosylase (TGase) is considered a promising antibiotic target due to its essential function and ready accessibility. TGase is located on the external surface of bacterial membrane so that inhibitors are easy to reach. 　　We has designed and synthesized some potential transglycosylase inhibitors with the aryl moiety bearing different substituents to mimic the saccharide part of lipid II, the natural substrate of TGase. On the other hand, a long chain phosphoglycerate, which is a characteristic portion of moenomycin, a natural TGase inhibitor, was used to mimic the long chain pyrophosphate part of lipid II. These kinds of inhibitors are expected to block the process of transglycosylation by mimicking the transition state of lipid II polymerization. 　　Some potential transglycosylase (TGase) inhibitors were synthesized and subjected to the HPLC-based TGase fluorescence assay and MIC assay. Among these derivatives of phosphoglycerate with the aryl moiety bearing different substituents, compounds 44 and 47 showed the best inhibition against TGase at 500 μM, and compound 44 has the best MIC value of 50 μM against Staphylococcus aureus. 　　We suggested that the appropriate substituent on the benzene ring could interact with the amide side chain of Asn275 in the active site of TGase to show a good inhibition. Based on the structures of 44 and 47, further introduction of hydrogen-bonding groups (e.g. OH) on the aryl moiety might improve the inhibitory activity to act as efficient TGase inhibitors.