Stefania Deceglie

Efficient mitochondrial biogenesis drives incomplete penetrance in Leber’s hereditary optic neuropathy

The mechanisms of incomplete penetrance in Leber’s hereditary optic neuropathy are elusive. Giordano et al. show that mitochondrial DNA content and mitochondrial mass are both increased in tissues and cells from unaffected mutation carriers relative to affected relatives and control individuals. Upregulation of mitochondrial biogenesis may represent a therapeutic target.

The MTERF family proteins: mitochondrial transcription regulators and beyond.

The MTERF family is a wide protein family, identified in Metazoa and plants, which consists of 4 subfamilies named MTERF1-4. Proteins belonging to this family are localized in mitochondria and show a modular architecture based on repetitions of a 30 amino acid module, the mTERF motif, containing leucine zipper-like heptads. The MTERF family includes the characterized transcription termination factors human mTERF, sea urchin mtDBP and Drosophila DmTTF. In vitro and in vivo studies show that these factors play different roles which are not restricted to transcription termination, but concern also transcription initiation and the control of mtDNA replication. The multiplicity of functions could be related to the differences in the gene organization of the mitochondrial genomes. Studies on the function of human and Drosophila MTERF3 factor showed that the protein acts as negative regulator of mitochondrial transcription, possibly in cooperation with other still unknown factors. The complete elucidation of the role of the MTERF family members will contribute to the unraveling of the molecular mechanisms of mtDNA transcription and replication.

Cigarette toxicity triggers Leber’s hereditary optic neuropathy by affecting mtDNA copy number, oxidative phosphorylation and ROS detoxification pathways

Leber’s hereditary optic neuropathy (LHON), the most frequent mitochondrial disease, is associated with mitochondrial DNA (mtDNA) point mutations affecting Complex I subunits, usually homoplasmic. This blinding disorder is characterized by incomplete penetrance, possibly related to several genetic modifying factors. We recently reported that increased mitochondrial biogenesis in unaffected mutation carriers is a compensatory mechanism, which reduces penetrance. Also, environmental factors such as cigarette smoking have been implicated as disease triggers. To investigate this issue further, we first assessed the relationship between cigarette smoke and mtDNA copy number in blood cells from large cohorts of LHON families, finding that smoking was significantly associated with the lowest mtDNA content in affected individuals. To unwrap the mechanism of tobacco toxicity in LHON, we exposed fibroblasts from affected individuals, unaffected mutation carriers and controls to cigarette smoke condensate (CSC). CSC decreased mtDNA copy number in all cells; moreover, it caused significant reduction of ATP level only in mutated cells including carriers. This implies that the bioenergetic compensation in carriers is hampered by exposure to smoke derivatives. We also observed that in untreated cells the level of carbonylated proteins was highest in affected individuals, whereas the level of several detoxifying enzymes was highest in carriers. Thus, carriers are particularly successful in reactive oxygen species (ROS) scavenging capacity. After CSC exposure, the amount of detoxifying enzymes increased in all cells, but carbonylated proteins increased only in LHON mutant cells, mostly from affected individuals. All considered, it appears that exposure to smoke derivatives has a more deleterious effect in affected individuals, whereas carriers are the most efficient in mitigating ROS rather than recovering bioenergetics. Therefore, the identification of genetic modifiers that modulate LHON penetrance must take into account also the exposure to environmental triggers such as tobacco smoke.

Contrahelicase activity of the mitochondrial transcription termination factor mtDBP

The sea urchin mitochondrial D-loop binding protein (mtDBP) is a transcription termination factor that is able to arrest bidirectionally mitochondrial RNA chain elongation. The observation that the mtDBP binding site in the main non-coding region is located in correspondence of the 3′ end of the triplex structure, where the synthesis of heavy strand mitochondrial (mt) DNA is either prematurely terminated or allowed to continue, raised the question whether mtDBP could also regulate mtDNA replication. By using a helicase assay in the presence of the replicative helicase of SV40, we show that mtDBP is able to inhibit the enzyme thus acting as a contrahelicase. The impairing activity of mtDBP is bidirectional as it is independent of the orientation of the protein binding site. The inhibition is increased by the presence of the guanosine-rich sequence that flanks mtDBP binding site. Finally, a mechanism of abrogation of mtDBP contrahelicase activity is suggested that is based on the dissociation of mtDBP from DNA caused by the passage of the RNA polymerase through the protein–DNA complex. All these findings favour the view that mtDBP, besides serving as transcription termination factor, could also act as a negative regulator of mtDNA synthesis at the level of D-loop expansion.

MTERF factors: a multifunction protein family.

Abstract The MTERF family is a large protein family, identified in metazoans and plants, which consists of four subfamilies, MTERF1, 2, 3 and 4. Mitochondrial localisation was predicted for the vast majority of MTERF family members and demonstrated for the characterised MTERF proteins. The main structural feature of MTERF proteins is the presence of a modular architecture, based on repetitions of a 30-residue module, the mTERF motif, containing leucine zipper-like heptads. The MTERF family includes transcription termination factors: human mTERF, sea urchin mtDBP and Drosophila DmTTF. In addition to terminating transcription, they are involved in transcription initiation and in the control of mtDNA replication. This multiplicity of functions seems to flank differences in the gene organisation of mitochondrial genomes. MTERF2 and MTERF3 play antithetical roles in controlling mitochondrial transcription: that is, mammalian and Drosophila MTERF3 act as negative regulators, whereas mammalian MTERF2 functions as a positive regulator. Both proteins contact mtDNA in the promoter region, perhaps establishing interactions, either mutual or with other factors. Regulation of MTERF gene expression in human and Drosophila depends on nuclear transcription factors NRF-2 and DREF, respectively, and proceeds through pathways which appear to discriminate between factors positively or negatively acting in mitochondrial transcription. In this emerging scenario, it appears that MTERF proteins act to coordinate mitochondrial transcription.

The sea urchin mitochondrial transcription factor A binds and bends DNA efficiently despite its unusually short C-terminal tail

Mitochondrial transcription factor A (TFAM) is a key component for the protection and transcription of the mitochondrial genome. TFAM belongs to the high mobility group (HMG) box family of DNA binding proteins that are able to bind to and bend DNA. Human TFAM (huTFAM) contains two HMG box domains separated by a linker region, and a 26 amino acid C-terminal tail distal to the second HMG box. Previous studies on huTFAM have shown that requisites for proper DNA bending and specific binding to the mitochondrial genome are specific intercalating residues and the C-terminal tail. We have characterized TFAM from the sea urchin Paracentrotus lividus (suTFAM). Differently from human, suTFAM contains a short 9 amino acid C-terminal tail, yet it still has the ability to specifically bind to mtDNA. To provide information on the mode of binding of the protein we used fluorescence resonance energy transfer (FRET) assays and found that, in spite of the absence of a canonical C-terminal tail, suTFAM distorts DNA at a great extent and recognizes specific target with high affinity. Site directed mutagenesis showed that the two Phe residues placed in corresponding position of the two intercalating Leu of huTFAM are responsible for the strong bending and the great binding affinity of suTFAM.

Characterization of the sea urchin mitochondrial transcription factor A reveals unusual features

Sea urchin mtDNA is transcribed via a different mechanism compared to vertebrates. To gain information on the apparatus of sea urchin mitochondrial transcription we have characterized the DNA binding properties of the mitochondrial transcription factor A (TFAM). The protein contains two HMG box domains but, differently from vertebrates, displays a very short C-terminal tail. Phylogenetic analysis showed that the distribution of tail length is mixed in the different lineages, indicating that it is a trait that undergoes rapid changes during evolution. Homology modeling suggests that the protein adopts the same configuration of the human counterpart and possibly a similar mode of binding to DNA. DNase I footprinting showed that TFAM specifically contacts mtDNA at a fixed distance from three AT-rich consensus sequences that were supposed to act as transcriptional initiation sites. Bound sequences are homologous and contain an inverted repeat motif, which resembles that involved in the intercalation of human TFAM in LSP DNA. The here reported data indicate that sea urchin TFAM specifically binds mtDNA. The protein could intercalate residues at the DNA inverted motif and, despite its short tail, might have a role in mitochondrial transcription.

A modified method for the purification of active large enzymes using the glutathione S-transferase expression system

The glutathione S-transferase (GST) fusion protein system is widely used for high-level expression and efficient purification of recombinant proteins from bacteria. However many GST-tagged proteins are insoluble, and the existing procedures, which employ a mixture of detergents to solubilize the molecules, frequently compromise their functional activity. A further limitation is that large proteins (>80 kDa) are poorly isolated by the current methods and are contaminated by truncated forms. To overcome these problems, we provide here an improved method for efficient purification of active large GST-tagged enzymes such as the 180-kDa GST-fused mitochondrial RNA polymerase.

Expression and purification of large active GST fusion enzymes.

GST fusion proteins expressed in bacteria often tend to form aggregates and are inefficiently purified by standard procedures, which employ a mixture of detergents that compromise the binding efficiency to the affinity resin and the biological activity of the recombinant proteins. Moreover, the binding to the resin is negatively affected by the molecular weight of the fusion protein. Here we report a simple and efficient method to purify active large GST-tagged proteins, which uses high ionic strength buffer to solubilize the protein aggregates in a bacterial lysate. Affinity-chromatography purification is achieved by adopting two columns connected in series, which facilitate the binding of large GST fused molecules. This approach was applied to purify the 180-kDa GST-tagged mitochondrial RNA polymerase. We also report conditions for simple and efficient GST tag removal from the eluted protein. Finally we demonstrate that the recombinant enzyme is capable to catalyze RNA synthesis.