OPEL is an elicitor protein identified in Phytophthora parasitica, which contains signal peptide in the N-terminus, followed by a thaumatin-like domain, a glycine rich domain and a GH16 domain. GH16 domain is characterized by the presence of a conserved active site for beta-1,3-glucanase. It has been shown previously that infiltration of OPEL recombinant protein into leaves of Nicotiana tabacum cv. Samsun-NN resulted in necrosis, callose deposition, ROS production as well as the induction of defense gene expression. Moreover, domain analysis indicated the elicitor activity of OPEL depends solely on the GH16 domain. Interestingly, the elicitor activity is compromised with OPEL recombinant protein harboring a single-point mutation in the predicted active site. It suggests an essential role of the enzymatic activity of OPEL in inducing plant defense responses, which might involve the generation of damage/danger-associated molecular pattern in the apoplast. To investigate this possibility, we prepared OPEL recombinant protein and OPEL mutant (OPEL-dm) with mutations at two key residues in the putative active site of the GH16 domain, infiltrated them individually into N. tabacum leaves, and then collected apoplastic fluid from the treated leaves, named AF-OPEL and AF-OPEL-dm, respectively. When infiltrated into tobacco leaves, AF-OPEL caused necrosis as well as induced defense gene expression and resistance against P. parasitica. In contrast, the activity of AF-OPEL-dm was significantly compromised. After heat treatment at 95 oC for 15 mins, AF-OPEL still retained most of its necrosis-inducing activity. Moreover, AF-OPEL contained more reducing sugars than AF-OPEL-dm. To identify the PTI-inducing substances, AF-OPEL was extracted by using n-hexane (H) and then ethyl acetate (EA) as the solvent, resulting in the collection of three fractions: AF-OPEL/H (low polar), AF-OPEL/EA (medium polar), and AF-OPEL/A (high polar). All three fractions induced ROS production as shown by the luminol-based chemiluminescence assay. However, the activity of AF-OPEL/EA was much higher than the other two.Further purification by high performance liquid chromatography (HPLC) identified three peaks (known as peak I, peak II, and peak III), which were found only in AF-OPEL/EA but not in the control experiment.Notably, only peak II induced ROS production. Based on these results, the mechanism for OPEL to induce PTI is through recognition of DAMP rather than PAMP and related to its putative site. In the future, we hope to identify the peak II-represented substance to understand the interaction between OPEL and plants.