Abstract ATP dependent proteases play important roles in controlling the levels of key regulatory protein and in the elimination of abnormal proteins to maintain normal physiological functions of microorgamisms. ClpYQ protease, one of ATP dependent proteases includes two subunits ClpY and ClpQ. ClpY acts as an ATPase and chaperone and ClpQ is a peptidase. ClpY is capble of forming a hexamer ring docked with ClpQ dodecamer to constitute a dumbbel-shaped complex. ClpY is responsible to recognize, unfold and traslocate substractes into the proteolytic site of ClpQ for degradation. Besides, ClpY is divided into three domains N, I and C domain. Each domain has it’s own distinct activity. I domain, a unique protruding domain of ClpY, is unclear for its function. In this study, our results demonstrated that ClpY I domain loop2 is responsible for the initial gripping of SulA and loop1 acts as a lid that is likely to prevent an excess of substracts binding for ClpY when ATP is present. ΔP1L2(aa 90-93；aa 175-209) showed the lowest binding activity with MBP-SulA at in vitro pull-down assay and these results indicated that pore I and loop2 are most responsiable for substrates binding. In addition, ClpY was capble of recognizing MBP-SulA wthout ATP to form SulA-ClpY complex and the ClpY hexamer can only bind a MBP-SulA molecule when ATP is present. These results also indicated that ClpY was capble to recognize SulA wthout ATP and formed SulA-ClpY complex for increasing its local surrounding substrate’s concentration and likely subsequently formed SulA-ClpY6 or SulA-ClpY12 complex docked with ClpQ for degradation when ATP is present. Y408A is not capble to form stable hexamer and ClpYQ oligomer maintains partial ATPase activity and degradation activity indicating that ClpYQ oligomerization is important for the enzyme activity.