With an alarming rise of antibiotic resistance in pathogenic bacteria, the number of casualties due to bacterial infection expediently increases. An emerging concept of anti-bacterial virulence has been developed. By compromising harmful effects of the virulent factors, the bacteria were disarmed and soon die out due to natural selection when competing for the resource with the “good” bacteria inhabited in our body. Lon protease, belonging to AAA+ (ATPase associated with a variety of cellular activities) superfamily, participates in the protein quality control and the degradation of several regulatory proteins crucial for well-regulated growth as well as virulence. So far, no degradation rule has been reported, and thus makes substrate screening difficult. In this study, we used Escherichia coli K-12 as model and identified EmrR and IhfB as the substrates of Lon. EmrR is a negative regulator of the multidrug resistance (MDR) efflux pump EmrAB in E. coli. By growth phase-dependent data sampling, we observed the degradation of EmrR was growth phase-dependent, which was in good agreement with emrRAB-based reporter assay. By gene deletion studies, we found that Lon-mediated nalidixic acid resistance was highly complicated since this phenomenon is comprised of more than one factor at a time, which cannot be well-explained by single protein participation model. However, the addition of nalidixic acid seemed irrelevant to Lon-dependent EmrR degradation. Together with growth-phase degradation and NA addition results, the stability of EmrR might be originated from the different DNA topology during the different growth phase. Along with protein alignment and docking calculation, we hypothesized the degron (degradation signal) of EmrR might be situated at the N- or C-terminus. Through circular dichroism and in vitro degradation assay, we believed the recognition of EmrR by Lon should be adaptor-mediated. By deletion and reporter assays, we found DnaK might serve as the critical adaptor for this degradation event to occur. To summarize, we observed a unique “chaperone-assisted proteolysis” in Lon-dependent EmrR proteolysis. These findings provided the importance of the “cross-talk” between chaperones and proteases for the properly targeted degradation. Also, the newly identified function of cell invasion in EmrR offers a direction for future drug development.