ClpYQ (HslUV) is an ATP-dependent protease from Escherichia coli, composed of the 49 kDa ClpY and 19 kDa ClpQ. ClpQ peptidase. The degradation of the abnormal proteins or the misfolded proteins is accomplished by this protease to avoid cell damage. When the cells are exposed to UV light or damaged by free radical, the SOS response induced a cell division inhibitor, SulA. ClpY recognizes its C-terminal 129 - 149 hydrophobic amino acids. However, SulA becomes inactive and aggregated while it lacks the last 20 amino acids. Also it was observed that HA-SulA*F143A was slowly degraded by ClpYQ. In addition, RcsA, as one of its substrates, is not clear for its direct targeted by ClpYQ. In this study, Western blot analysis was used to determine how ClpY is to recognize SulA ΔC20, and SulA*F143A. As results, ClpY recognizes SulAΔC20 and SulA*F143A in a similar way as it did to the wild-type SulA. We showed here that the C129 - 149 region of SulA is related to the monomer or dimer formation. The aromatic ring of ClpY91 (tyrosine,Tyr) is, however, known necessary for the translocation of substrates. In addition, through our study, we also showed that the hydroxyl-group of ClpY91 (Tyr) plays an important role in translocating of the substrates to ClpQ. From an alternative approach, we adopted the assays of β-galactosidase activity of cpsB::lacZ with pTH18kr-rcsA with or without ClpYQ. We found that the activity of RcsA decreases with an increased temperature, and the β-galactosidase levels decrease when ClpYQ is present. Through Western blot analysis, it was shown that the accumulation of RcsA was equal under the different temperature. However, it was reduced when expressing the ClpYQ protease. Therefore, RcsA is one of the substrates for ClpYQ. In addition, we also demonstrated that ClpY recognizes RcsA in a similar way as it did toward SulA.