In recent years, the switching of magnetic states by using current in magnetoresistive random access memory has attracted great attentions due to the newly discovered spin-transfer torque (STT) effect in magnetic tunneling junctions. In order to study the interfacial effects on the STT effect in the single molecular magnetic junction, we choose two kinds of molecule with different anchoring ions, 1,4-benzenediamine (BDA) and 1,4-benzenedithol (BDT), sandwiched by two Co(111) nanowires. To simulate the stretching effect, we first increase the distance between two electrodes step by step, and then optimize the structures of each step by using the first-principles calculations, until the junction is breakdown. The NEGF-DFT+LDA calculation is further employed to obtain the spin-polarized transmission spectra and the projected density of states. Although the similar breakdown behavior can be observed in both junctions, our calculation results suggest the superior spin transfer via amine-ended Co/BDA/Co junction, due to the strong coupling between N-p orbital and Co-d orbitals at the Fermi energy. This is in sharp contrast to the traditional molecular junction, where thiol-ended π-conjugated molecule mediates a better electron charge transfer between non-magnetic electrodes. Such NH-anchoring-induced spin-filtering effect, resulting from the significant and broad spin-up transmission features solely in PC configuration, not only gives rise to the high MR value, which can reach up to about 700% under low bias, but also leads to the giant magnitude of STT, which is about three order larger than that of conventional MgO-based MTJs. Theses interesting findings suggest that amine-ended π-saturated single molecular magnetic junction may open a novel and promising organic-based- STT-MRAM applications.