Inhibition of Human Peptide Deformylase Disrupts Mitochondrial Function

Deformylases are metalloproteases in bacteria, plants, and humans that remove the N-formyl-methionine off peptides in vitro. The human homolog of peptide deformylase (HsPDF) resides in the mitochondria, along with its putative formylated substrates; however, the cellular function of HsPDF remains elusive. Here we report on the function of HsPDF in mitochondrial translation and oxidative phosphorylation complex biogenesis. Functional HsPDF appears to be necessary for the accumulation of mitochondrial DNA-encoded proteins and assembly of new respiratory complexes containing these proteins. Consequently, inhibition of HsPDF reduces respiratory function and cellular ATP levels, causing dependence on aerobic glycolysis for cell survival. A series of structurally different HsPDF inhibitors and control peptidase inhibitors confirmed that inhibition of HsPDF decreases mtDNA-encoded protein accumulation. Therefore, HsPDF appears to have a role in maintenance of mitochondrial respiratory function, and this function is analogous to that of chloroplast PDF.The human mitochondrial protein peptide deformylase, HsPDF, is a metalloprotease that removes the formyl moiety on the methionine of N-formyl-methionine peptide substrates in an enzymatic assay (24, 35). Despite the slow kinetic properties of HsPDF in an in vitro deformylation assay (24, 29, 35), we have shown that small interfering RNA (siRNA) interference of HsPDF decreases human cancer cell proliferation. Similarly, pharmacologic inhibition with the PDF antibiotic inhibitor actinonin and its analogs results in mitochondrial membrane depolarization and promotes cell death or proliferation arrest in a wide variety of cancer cell lines (18, 25). However, the cellular function of HsPDF remains elusive, and others have proposed that it has none (29). In bacteria, deformylation of nascent peptides is necessary for removal of the N-terminal methionine (36) and posttranslational processing of at least a subset of proteins that contribute to cell growth and viability (28). Prokaryotic PDF thus fulfills a role in cotranslational processing (7) and in protein degradation (41).In mammals, N-terminal formylation of proteins is only known to occur during mitochondrial translation initiation, as in prokaryotic protein translation (6). In contrast to bacteria, where the entire proteome is formylated for translation initiation, formylation in eukaryotes is limited to the 13 mitochondrial DNA (mtDNA)-encoded proteins. Formylation is important for mitochondrial translation, because formyl-Met-tRNA, but not Met-tRNA, is recognized by initiation factor 2 as the initiator tRNA (26, 37, 39). Therefore, the participation of HsPDF in protein post- or cotranslational processing can be narrowed down to these mitochondrial translation products.Despite the current understanding of the function of formyl-methionine in the initiation of protein synthesis in mammalian mitochondria (38, 39), the functional relevance of the downstream processing of nascent mitochondrial translation products has remained unexplored. Furthermore, it has been assumed that human mitochondria-encoded proteins, like those of bovine origin, are generally not deformylated after synthesis (45).The mammalian mitochondrial genome-encoded proteins are all subunits of four of the five oxidative phosphorylation respiratory chain enzyme complexes (I, III, IV, and V) (2, 40, 42). Respiratory complexes are comprised of multiple proteins. With the exception of complex II, which is comprised entirely of nuclear DNA-encoded subunits, all other complexes include both nuclear and mitochondrial DNA-encoded proteins. Synthesis of key mtDNA-encoded protein subunits, and the assembly of these proteins with multiple nuclear-encoded subunits within the mitochondria, is necessary for the function of each individual complex (16, 30, 44). Moreover, a functional interdependence among stably assembled respiratory complexes has been demonstrated (1). Mutations in human mtDNA that affect protein-coding regions or nuclear DNA mutations that affect expression of respiratory complex subunits cause disease (13), including Parkinson''s disease, for example, in which decreased respiratory function and compromised cell viability have been demonstrated (5, 21, 23). Therefore, the importance of properly assembled mitochondrial respiratory complexes suggests that their disruption, by inhibition of mtDNA-encoded protein processing, could have significant effects on cellular function.We hypothesized that HsPDF-mediated processing of mtDNA-encoded proteins is necessary for proper function of the respiratory chain complexes. To determine how the human deformylase activity contributes to cellular function, we used pharmacologic inhibition of HsPDF activity with the hydroxamic acid peptidomimetic inhibitor of PDF, actinonin, and confirmed our findings with a variety of other structurally different inhibitors. PDF has been shown to be a target of actinonin in bacteria (9), human cells (24), and plants (17).Here we show that inhibition of HsPDF function in mitochondria of human cell lines reduces mtDNA-encoded protein accumulation, new respiratory complex assembly, and energy production by the mitochondria. Aerobic glycolysis-dependent cell survival ensues upon disruption of HsPDF function. Therefore, HsPDF appears to fulfill a function in the mitochondria and to have a role in mtDNA-encoded protein-containing oxidative phosphorylation (OXPHOS) complex biogenesis.