Transglycosylase (TGase) is an attractive target for development of new antibiotics due to its location outside the membrane of bacteria and essential role in peptidoglycan synthesis. Some TGase inhibitors have been identified, but none of them have been developed into antibiotics for human. The existing TGase assays are not fast enough to develop new antibiotics. Therefore a continuous, quantitative, and high-throughput assay for TGase will facilitate the discovery of new and effective inhibitors. We chose 4′-(4-N,N-dimethylaminophenyl)-2,2′:6′,2″-terpyridine as the ligand (L) of Zn(II) ion to form a complex ZnCl2L (9) as the TGase probe, which has been reported as a fluorescent sensor of inorganic pyrophosphate. To establish a model system, we first synthesized GlcNAc–GPP (23) instead of lipid II, and the commercially available farnesyl pyrophosphate (FPP) was used as the truncated analogue of undecaprenyl pyrophosphate (C55-PP) to compare the binding behavior with sensor 9. The experiment showed that FPP was selectively bound with 9 to emit fluorescence at 650 nm. In contrast, GlcNAc–GPP 23–9 did not emit fluorescence. Next, the sensor 9 was applied in TGase assay which was in a more complex solution system. NBD–lipid II was utilized as the substrate for the TGase assay, and sensor 9 was added to monitor the change of fluorescence between the reacted group and unreacted group. The result showed an unexpected fluorescence quenching effect of NBD-lipid II at 550 nm, but enhancement at a longer wavelength of 650 nm that was presumably caused by complexation of NBD-lipid II with 9. Although the result was opposite to our prediction, the TGase catalyzed reaction could still be monitored by fluorescence at 550 nm. In summary, we successfully developed a TGase assay in which sensor 9 was utilized to track the enzymatic reaction. This system could be operated as a high-throughput assay for screening TGase inhibitors in the future.