The conductance of single-molecule junctions for a tricobalt metal-string complex [Co3(dpa)4(NCS)2] was investigated under magnetic influence and measured by scanning tunneling microscopy-based break junction (STM BJ) technique. The metal-molecule-metal (MMM) junctions were configured by Au- or Ni-tips of the STM and a piece of Au substrate. For the Ni-Au pair of electrodes, the junction conductance was associated with whether the magnet’s north or south pole faced the Ni-tip. For the control experiments using Au-Au electrodes, the magnetic field had little effect on conductance. Spin-polarized transmission spectra were calculated by non-equilibrium Green's function-density functional theory (NEGF-DFT) and showed a transmission peak of β-spin closer to the electrode Fermi energy than that of the α-spin one, indicating that the magnetic and tranpsport properties of the molecule were dominated by β-spin electron. Proposed herein is a DOS-based model (density of states) in which the magnetized nickel electrode influenced the energy of β-spin transmission peaks. Additionally, the spin-orbit coupling (SOC) effect from gold and the spin delocalization of the molecule led to spin polarization and the consequent DOS splitting in the gold electrode. In conclusion, this study shows the electron-transporting behavior across Au-[Co3(dpa)4(NCS)2]-Ni junctions under the influence of a 0.22-Tesla magnet.