Single-layered transition-metal-dichalcogenides (TMDs), i.e. MoS2, are well known for their non-trivial valleytronic properties for such as valley-based memory or quantum computing. Exchange-coupling TMDs with ferromagnetic materials has been regarded as an important approach to manipulate the valley degree of freedom via the proximity effect, so the magnetism can serve to bridge the spin and valley in the single-layered TMDs. This work reports a study concerning how the proximity effect can be induced in a ferrimagnetic yttrium iron garnet (YIG)/MoS_2 bilayer and be resolved by using a magnetic circular dichroism (MCD) spectroscopy. It reveals the proximity effect in the bilayer originates from a spin-transfer at the interface of YIG/MoS_2, in which the minority spin of YIG would transfer to the conduction valley of MoS_2 and make the spin-polarized valley antiferromagnetically coupled with YIG's majority spins. The spin-transfer-associated proximity effect can be precisely resolved by using MCD technique. It provides an ideal research tool to study the proximity-related issues in the TMD-based exchange-coupled bilayer.