Organic spin valves (OSVs) with a thin organic semiconductor (OSC) spacer of 3,4,9,10-perylene-teracarboxylic dianhydride (PTCDA) were fabricated using magneto-sputtering and thermal evaporating technique, and characterized by DC four-probe sensing, AC two-terminal measuring analysis technique to discuss the magnetic and electric properties at room temperature. The magnetoresistance ratio of 14.6% and the magnetocapacitance of -1.93% were demonstrated in the OSV with 2nm-PTCDA spacer at room temperature. To figure out the negative interfacial capacitances, we speculate that the behavior is attributed to the charge accumulation at the metal-organic interfacial dipole layer and the diffusion layer induced by band bending. The capacitive property is different to the Al2O3-based magnetic tunnelling junction. Furthermore, the influence of spacer thickness to magnetoimpedance and interfacial capacitance in OSVs with three different thickness spacers are investigated. Working out that the cut-off frequency is got smaller as the OSV spacer became thicker in magnetoimpedance spectrum. The influence of spacer thickness to magnetocapacitance performance is decay with the same to magnetoresistance, and that charge accumulation at the interface states can be affected by the thickness of the PTCDA-spacer. Briefly, the interfacial capacitance related to the spacer thickness and characteristic using the analysis technique of magnetocapacitance is demonstrated, which provide the information about the capacitive and interfacial properties in PTCDA-OSV system.