GaN vertical power transistors have gained increasing interest in recent years due to the advantages over lateral transistors in high voltage/high current applications. To date, two major topologies have been studied most: gate-on-epi-surface (GoE) and gate-on-sidewall (GoS). The GoE devices include CAVET [1] and VDMOSFET-like transistors [2, 3]. The GoS devices include U-MOS or trench-MOSFETs with inversion channel [4, 5] or regrown AlGaN/GaN semi-polar channel [6], as well as depletion-mode MISFET [7]. The vertical MISFET is the simplest to fabricate, however, it does not have avalanche capabilities inherently besides being difficult to achieve sufficiently large Vth. It is easier for trench MOSFETs to achieve normally-off operation, high breakdown voltage (BV) and small footprint. However, it is challenging to achieve high mobility in the inversion channel. In contrast, CAVETs, VDMOS-like transistors and PolarMOS [3] utilize high mobility AlGaN/GaN channel to achieve low Ron, but the channel regrowth posts challenges in achieving low off-state leakage in un-gated regrowth interface. Recently, a novel design based on trench MOSFET is realized by MOCVD regrowth of a thin GaN interlayer [8]. Low Ron and high BV is achieved in the gated regrown channel. Similar to the other MOCVD regrown devices, the buried Mg-doped p-GaN needs to be re-activated by exposing the p-GaN surface during high temperature anneal. This leads to high thermal budget and poses limitations on device geometry. Furthermore, any incomplete activation of buried p-GaN leads to reduced BV. In this work, we design a V-shaped trench MOSFET with MBE regrown UID GaN channel. −600 V breakdown voltage with normally-off operation is demonstrated without the need for re-activation of the buried p-GaN. To our knowledge, this is the highest BV achieved in GaN vertical transistors with MBE regrown channel.