In modern processor architectures, the register file (RF) consumes considerable amount of the processor power. It is well known that by allowing software to have explicit fine-grained control over the datapath, the transport-triggered architectures (TTAs) can substantially reduce the RF traffic, thereby minimizing the RF energy. However, it is important to make sure that the gain in RF is not cancelled out by the overhead due to the fine-grained datapath control, in particular, the deterioration of code density in conventional TTAs. In this paper, we analyze the potential of minimizing RF energy in MOVE-Pro, a TTA-based processor framework. We present a flexible compiler backend, which performs energy-aware instruction scheduling to push the limit of RF energy reduction. The experimental results show that with the proposed energy-aware compiler backend, MOVE-Pro is able to significantly reduce RF energy compared to its RISC/VLIW counterparts, by up to 80%. Meanwhile the code density of MOVE-Pro remains at the same level as its RISC/VLIW counterparts, allowing the energy saving in RF to be successfully transferred to total energy saving.