NME3, a member of nucleoside diphosphate kinase (NDPK) family, is capable of transferring a phosphate from a nucleoside triphosphate to a nucleoside diphosphate by a ping-pong reaction via its histidine kinase activity. Our laboratory has previously demonstrated that NME3 has a function in stimulation of MFN-mediated mitochondrial fusion. Knockdown of NME3 increases fragmented mitochondria while overexpression of NME3 leads to mitochondrial clustering, suggesting the importance of expression level of NME3 in maintaining mitochondrial dynamics. Using an inducible system, I presented evidence that NME3 is a highly unstable protein degraded by ubiquitin-proteasome system dependent on its N-terminus-mediated mitochondrial anchoring. MUL1, an E3 ligase localized on outer membrane of mitochondria, was identified to be responsible for ubiquitination and proteolysis of NME3. In response to hypoxia, NME3 is upregulated to mediate mitochondrial clustering. The E3 ligase activity of MUL1 is reduced by hypoxia-induced oxidative stress. Most interestingly, NME3 also suppresses MUL1 activity through phosphorylation of H319 via histidine kinase activity. As such, catalytic-dead mutant has a shorter half-life than wild-type of NME3. Therefore, the reciprocal regulation between NME3 and MUL1 exerts an opposite control in mitochondrial morphology.