Ruolo delle alterazioni mitocondriali indotte dall'ipossia nella patogenesi della malattia di alzheimer

Le alterazioni della funzionalità mitocondriale detengono un ruolo cruciale nella patogenesi della malattia di Alzheimer (AD), sostenendo il processo neurodegenerativo attraverso meccanismi quali la riduzione della disponibilità energetica e la iperproduzione di ROS. Alle numerose ipotesi di patogenesi dell’AD, si è recentemente affiancata la cosiddetta ipotesi vascolare. Nei soggetti AD è stata riscontrata una significativa riduzione della disponibilità di ossigeno a livello neuronale (ipossia neuronale). Da numerosi studi è poi emerso che l’ipossia gioca un ruolo fondamentale nello sviluppo dell’AD contribuendo a più vie patogenetiche contemporaneamente. Tuttavia, non sono stati ancora chiariti tutti i meccanismi attraverso cui l’ipossia esplica la sua azione di danno. Lo scopo di questo studio è stato quello di contribuire a chiarire il ruolo patologico dell’ipossia nell’AD, analizzando principalmente le alterazioni della funzionalità mitocondriale indotte dalla riduzione della disponibilità di ossigeno. Nella prima fase dello studio cellule PC12 sono state coltivate in presenza di β-amiloide e ipossia. In questo modello abbiamo osservato un potenziamento dei fenomeni di deplezione dell’ATP e di generazione delle ROS indotti dalla Aβ quando anche l’ipossia era presente come fonte di danno cellulare, ipotizzando per i due fattori un effetto congiunto di tipo additivo. Nella seconda fase abbiamo esposto all’ipossia fibroblasti prelevati da pazienti AD portatori di mutazioni a carico dei geni APP e PSEN. La presenza di mutazioni predisponenti ad un fenotipo AD era in grado di determinare un danno bioenergetico e ossidativo. Le alterazioni bioenergetiche riscontrate in normossia risultavano ulteriormente potenziate quando i fibroblasti erano coltivati in ipossia, mentre lo stato di stress ossidativo veniva evidenziato solo in condizioni ipossiche. Sulla base dei risultati finora conseguiti si può ipotizzare che uno dei meccanismi attraverso cui l’ipossia esplica la sua azione di danno nella AD, possa essere dovuto alla capacità di potenziare ulteriormente le alterazioni della funzionalità mitocondriale.

Studi funzionali e strutturali sul wildtype e sul mutante γM23-K della ATP sintasi di Rhodobacter capsulatus: ruolo dell'ADP e della forza protonmotiva nell'attivazione dell’enzima e nell'accoppiamento dell'idrolisi di ATP alla traslocazione protonica

Nel presente lavoro di tesi sono state messe a confronto le ATP sintasi wild-type e γM23-K in cromatofori del batterio fotosintetico Rhodobacter capsulatus sotto gli aspetti funzionale e regolatorio. Si pensava inizialmente che la mutazione, in base a studi riportati in letteratura condotti sull’omologa mutazione in E. coli, avrebbe indotto disaccoppiamento intrinseco nell’enzima. Il presente lavoro ha chiarito che il principale effetto della mutazione è un significativo aumento dell’affinità dell’enzima per l’ADP inibitorio, che ne determina il ridotto livello di ATP idrolisi e la rapidissima reinattivazione in seguito ad attivazione da forza protonmotiva. Il residuo 23 della subunità γ si trova posizionato in prossimità della regione conservata DEELSED carica negativamente della subunità β, e l’introduzione nel mutante di una ulteriore carica positiva potrebbe determinare una maggiore richiesta di energia per indurre l’apertura del sito catalitico. Un’analisi quantitativa dei dati di proton pumping condotta mediante inibizione parziale dell’idrolisi del wildtype ha inoltre mostrato come il grado di accoppiamento del mutante in condizioni standard non differisca sostanzialmente da quello del wild-type. D’altro canto, è stato recentemente osservato come un disaccoppiamento intrinseco possa venire osservato in condizioni opportune anche nel wild-type, e cioè a basse concentrazioni di ADP e Pi. Nel presente lavoro di tesi si è dimostrato come nel mutante l’osservazione del fenomeno del disaccoppiamento intrinseco sia facilitata rispetto al wild-type. È stato proprio nell’ambito delle misure condotte sul mutante che è stato possibile dimostrare per la prima volta il ruolo fondamentale della componente elettrica della forza protonmotiva nel mantenere lo stato enzimatico ad elevato accoppiamento. Tale ruolo è stato successivamente messo in luce anche nel wild-type, in parte anche grazie all’uso di inibitori specifici di F1 e di FO. Il disaccoppiamento intrinseco nel wild-type è stato ulteriormente esaminato anche nella sua dipendenza dalla rimozione di ADP e Pi; in particolare, oltre all’amina fluorescente ACMA, è stata utilizzata come sonda di ΔpH anche la 9-aminoacridina e come sonda di Δψ l’Oxonolo VI. In entrambi i casi il ruolo accoppiante di questi due ligandi è stato confermato, inoltre utilizzando la 9-aminoacridina è stato possibile calibrare il segnale di fluorescenza con salti acido-base, dando quindi una base quantitativa ai dati ottenuti. Noi riteniamo che il più probabile candidato strutturale coinvolto in questi cambiamenti di stato enzimatici sia la subunità ε, di cui è noto il coinvolgimento in processi di regolazione e in cambiamenti strutturali indotti da nucleotidi e dalla forza protonmotiva. In collaborazione con il Dipartimento di Chimica Fisica dell’Università di Friburgo è in atto un progetto per studiare i cambiamenti strutturali presumibilmente associati al disaccoppiamento intrinseco tramite FRET in singola molecola di complessi ATP-sintasici marcati con fluorofori sia sulla subunità ε che sulla subunità γ. Nell’ambito di questa tesi sono stati creati a questo fine alcuni doppi mutanti cisteinici ed è stato messo a punto un protocollo per la loro marcatura con sonde fluorescenti.

Intrinsic uncoupling in the ATP synthase of Escherichia coli. Studies on WT and ε-truncated mutants

The H+/ATP ratio in the catalysis of ATP synthase has generally been considered a fixed parameter. However, Melandri and coworkers have recently shown that, in the ATP synthase of the photosynthetic bacterium Rb.capsulatus, this ratio can significantly decrease during ATP hydrolysis when the concentration of either ADP or Pi is maintained at a low level (Turina et al., 2004). The present work has dealt with the ATP synthase of E.coli, looking for evidence of this phenomenon of intrinsic uncoupling in this organism as well. First of all, we have shown that the DCCD-sensitive ATP hydrolysis activity of E.coli internal membranes was strongly inhibited by ADP and Pi, with a half-maximal effect in the submicromolar range for ADP and at 140 µM for Pi. In contrast to this monotonic inhibition, however, the proton pumping activity of the enzyme, as estimated under the same conditions by the fluorescence quenching of the ΔpH-sensitive probe ACMA, showed a clearly biphasic progression, both for Pi, increasing from 0 up to approximately 200 µM, and for ADP, increasing from 0 up to a few µM. We have interpreted these results as indicating that the occupancy of ADP and Pi binding sites shifts the enzyme from a partially uncoupled state to a fully coupled state, and we expect that the ADP- and Pi-modulated intrinsic uncoupling is likely to be a general feature of prokaryotic ATP synthases. Moreover, the biphasicity of the proton pumping data suggested that two Pi binding sites are involved. In order to verify whether the same behaviour could be observed in the isolated enzyme, we have purified the ATP synthase of E.coli and reconstituted it into liposomes. Similarly as observed in the internal membrane preparation, in the isolated and reconstituted enzyme it was possible to observe inhibition of the hydrolytic activity by ADP and Pi (with half-maximal effects at few µM for ADP and at 400 µM for Pi) with a concomitant stimulation of proton pumping. Both the inhibition of ATP hydrolysis and the stimulation of proton pumping as a function of Pi were lost upon ADP removal by an ADP trap. These data have made it possible to conclude that the results obtained in E.coli internal membranes are not due to the artefactual interference of enzymatic activities other than the ones of the ATP synthase. In addition, data obtained with liposomes have allowed a calibration of the ACMA signal by ΔpH transitions of known extent, leading to a quantitative evaluation of the proton pumping data. Finally, we have focused our efforts on searching for a possible structural candidate involved in the phenomenon of intrinsic uncoupling. The ε-subunit of the ATP-synthase is known as an endogenous inhibitor of the hydrolysis activity of the complex and appears to undergo drastic conformational changes between a non-inhibitory form (down-state) and an inhibitory form (up-state)(Rodgers & Wilce, 2000; Gibbons et al., 2000). In addition, the results of Cipriano & Dunn (2006) indicated that the C-terminal domain of this subunit played an important role in the coupling mechanism of the pump, and those of Capaldi et al. (2001), Suzuki et al. (2003) were consistent with the down-state showing a higher hydrolysis-to-synthesis ratio than the up-state. Therefore, we decided to search for modulation of pumping efficiency in a C-terminally truncated ε mutant. A low copy number expression vector has been built, carrying an extra copy of uncC, with the aim of generating an ε-overexpressing E.coli strain in which normal levels of assembly of the mutated ATP-synthase complex would be promoted. We have then compared the ATP hydrolysis and the proton pumping activity in membranes prepared from these ε-overexpressing E.coli strains, which carried either the WT ε subunit or the ε88-stop truncated form. Both strains yielded well energized membranes. Noticeably, they showed a marked difference in the inhibition of hydrolysis by Pi, this effect being largely lost in the truncated mutant. However, pre-incubation of the mutated enzyme with ADP at low nanomolar concentrations (apparent Kd = 0.7nM) restored the hydrolysis inhibition, together with the modulation of intrinsic uncoupling by Pi, indicating that, contrary to wild-type, during membrane preparation the truncated mutant had lost the ADP bound at this high-affinity site, evidently due to a lower affinity (and/or higher release) for ADP of the mutant relative to wild type. Therefore, one of the effects of the C-terminal domain of ε appears to be to modulate the affinity of at least one of the binding sites for ADP. The lack of this domain does not appear so much to influence the modulability of coupling efficiency, but instead the extent of this modulation. At higher preincubated ADP concentrations (apparent Kd = 117nM), the only observed effects were inhibition of both hydrolysis and synthesis, providing a direct proof that two ADP-binding sites on the enzyme are involved in the inhibition of hydrolysis, of which only the one at higher affinity also modulates the coupling efficiency.

Studies of OPA1 pathogenic mechanisms in Dominant Optic Atrophy and novel protein function in mitochondrial DNA stability

The mitochondrion is an essential cytoplasmic organelle that provides most of the energy necessary for eukaryotic cell physiology. Mitochondrial structure and functions are maintained by proteins of both mitochondrial and nuclear origin. These organelles are organized in an extended network that dynamically fuses and divides. Mitochondrial morphology results from the equilibrium between fusion and fission processes, controlled by a family of “mitochondria-shaping” proteins. It is becoming clear that defects in mitochondrial dynamics can impair mitochondrial respiration, morphology and motility, leading to apoptotic cell death in vitro and more or less severe neurodegenerative disorders in vivo in humans. Mutations in OPA1, a nuclear encoded mitochondrial protein, cause autosomal Dominant Optic Atrophy (DOA), a heterogeneous blinding disease characterized by retinal ganglion cell degeneration leading to optic neuropathy (Delettre et al., 2000; Alexander et al., 2000). OPA1 is a mitochondrial dynamin-related guanosine triphosphatase (GTPase) protein involved in mitochondrial network dynamics, cytochrome c storage and apoptosis. This protein is anchored or associated on the inner mitochondrial membrane facing the intermembrane space. Eight OPA1 isoforms resulting from alternative splicing combinations of exon 4, 4b and 5b have been described (Delettre et al., 2001). These variants greatly vary among diverse organs and the presence of specific isoforms has been associated with various mitochondrial functions. The different spliced exons encode domains included in the amino-terminal region and contribute to determine OPA1 functions (Olichon et al., 2006). It has been shown that exon 4, that is conserved throughout evolution, confers functions to OPA1 involved in maintenance of the mitochondrial membrane potential and in the fusion of the network. Conversely, exon 4b and exon 5b, which are vertebrate specific, are involved in regulation of cytochrome c release from mitochondria, and activation of apoptosis, a process restricted to vertebrates (Olichon et al., 2007). While Mgm1p has been identified thanks to its role in mtDNA maintenance, it is only recently that OPA1 has been linked to mtDNA stability. Missense mutations in OPA1 cause accumulation of multiple deletions in skeletal muscle. The syndrome associated to these mutations (DOA-1 plus) is complex, consisting of a combination of dominant optic atrophy, progressive external ophtalmoplegia, peripheral neuropathy, ataxia and deafness (Amati- Bonneau et al., 2008; Hudson et al., 2008). OPA1 is the fifth gene associated with mtDNA “breakage syndrome” together with ANT1, PolG1-2 and TYMP (Spinazzola et al., 2009). In this thesis we show for the first time that specific OPA1 isoforms associated to exon 4b are important for mtDNA stability, by anchoring the nucleoids to the inner mitochondrial membrane. Our results clearly demonstrate that OPA1 isoforms including exon 4b are intimately associated to the maintenance of the mitochondrial genome, as their silencing leads to mtDNA depletion. The mechanism leading to mtDNA loss is associated with replication inhibition in cells where exon 4b containing isoforms were down-regulated. Furthermore silencing of exon 4b associated isoforms is responsible for alteration in mtDNA-nucleoids distribution in the mitochondrial network. In this study it was evidenced that OPA1 exon 4b isoform is cleaved to provide a 10kd peptide embedded in the inner membrane by a second transmembrane domain, that seems to be crucial for mitochondrial genome maintenance and does correspond to the second transmembrane domain of the yeasts orthologue encoded by MGM1 or Msp1, which is also mandatory for this process (Diot et al., 2009; Herlan et al., 2003). Furthermore in this thesis we show that the NT-OPA1-exon 4b peptide co-immuno-precipitates with mtDNA and specifically interacts with two major components of the mitochondrial nucleoids: the polymerase gamma and Tfam. Thus, from these experiments the conclusion is that NT-OPA1- exon 4b peptide contributes to the nucleoid anchoring in the inner mitochondrial membrane, a process that is required for the initiation of mtDNA replication and for the distribution of nucleoids along the network. These data provide new crucial insights in understanding the mechanism involved in maintenance of mtDNA integrity, because they clearly demonstrate that, besides genes implicated in mtDNA replications (i.e. polymerase gamma, Tfam, twinkle and genes involved in the nucleotide pool metabolism), OPA1 and mitochondrial membrane dynamics play also an important role. Noticeably, the effect on mtDNA is different depending on the specific OPA1 isoforms down-regulated, suggesting the involvement of two different combined mechanisms. Over two hundred OPA1 mutations, spread throughout the coding region of the gene, have been described to date, including substitutions, deletions or insertions. Some mutations are predicted to generate a truncated protein inducing haploinsufficiency, whereas the missense nucleotide substitutions result in aminoacidic changes which affect conserved positions of the OPA1 protein. So far, the functional consequences of OPA1 mutations in cells from DOA patients are poorly understood. Phosphorus MR spectroscopy in patients with the c.2708delTTAG deletion revealed a defect in oxidative phosphorylation in muscles (Lodi et al., 2004). An energetic impairment has been also show in fibroblasts with the severe OPA1 R445H mutation (Amati-Bonneau et al., 2005). It has been previously reported by our group that OPA1 mutations leading to haploinsufficiency are associated in fibroblasts to an oxidative phosphorylation dysfunction, mainly involving the respiratory complex I (Zanna et al., 2008). In this study we have evaluated the energetic efficiency of a panel of skin fibroblasts derived from DOA patients, five fibroblast cell lines with OPA1 mutations causing haploinsufficiency (DOA-H) and two cell lines bearing mis-sense aminoacidic substitutions (DOA-AA), and compared with control fibroblasts. Although both types of DOA fibroblasts maintained a similar ATP content when incubated in a glucose-free medium, i.e. when forced to utilize the oxidative phosphorylation only to produce ATP, the mitochondrial ATP synthesis through complex I, measured in digitonin-permeabilized cells, was significantly reduced in cells with OPA1 haploinsufficiency only, whereas it was similar to controls in cells with the missense substitutions. Furthermore, evaluation of the mitochondrial membrane potential (DYm) in the two fibroblast lines DOA-AA and in two DOA-H fibroblasts, namely those bearing the c.2819-2A>C mutation and the c.2708delTTAG microdeletion, revealed an anomalous depolarizing response to oligomycin in DOA-H cell lines only. This finding clearly supports the hypothesis that these mutations cause a significant alteration in the respiratory chain function, which can be unmasked only when the operation of the ATP synthase is prevented. Noticeably, oligomycin-induced depolarization in these cells was almost completely prevented by preincubation with cyclosporin A, a well known inhibitor of the permeability transition pore (PTP). This results is very important because it suggests for the first time that the voltage threshold for PTP opening is altered in DOA-H fibroblasts. Although this issue has not yet been addressed in the present study, several are the mechanisms that have been proposed to lead to PTP deregulation, including in particular increased reactive oxygen species production and alteration of Ca2+ homeostasis, whose role in DOA fibroblasts PTP opening is currently under investigation. Identification of the mechanisms leading to altered threshold for PTP regulation will help our understanding of the pathophysiology of DOA, but also provide a strategy for therapeutic intervention.

The inhibition of aerobic glycolysis as a therapeutic approach to improve cancer chemotherapy

The aim of the research project discussed in this thesis was to study the inhibition of aerobic glycolysis, that is the metabolic pathway exploited by cancer cells for the ATP generation. This observation has led to the evaluation of glycolytic inhibitors as potential anticancer agents. Lactate dehydrogenase (LDH) is the only enzyme whose inhibition should allow a blocking of aerobic glycolysis of tumor cells without damaging the normal cells which, in conditions of normal functional activity and sufficient oxygen supply, do not need this enzyme. In preliminar experiments we demonstrated that oxamic acid and tartronic acid, two LDH competitive inhibitors, impaired aerobic glycolysis and replication of cells from human hepatocellular carcinoma. Therefore, we proposed that the depletion of ATP levels in neoplastic cells, could improved the chemotherapeutic index of associated anticancer drugs; in particular, it was studied the association of oxamic acid and multi-targeted kinase inhibitors. A synergistic effect in combination with sorafenib was observed, and we demonstrated that this was related to the capacity of sorafenib to hinder the oxidative phosphorylation, so that cells were more dependent to aerobic glycolysis. These results linked to LDH blockage encouraged us to search for LDH inhibitors more powerful than oxamic acid; thus, in collaboration with the Department of Pharmaceutical Sciences of Bologna University we identified a new molecule, galloflavin, able to inhibit both A and B isoforms of LDH enzyme. The effects of galloflavin were studied on different human cancer cell lines (hepatocellular carcinoma, breast cancer, Burkitt’s lymphoma). Although exhibiting different power on the tested cell lines, galloflavin was constantly found to inhibit lactate and ATP production and to induce cell death, mainly in the form of apoptosis. Finally, as LDH-A is able to bind single stranded DNA, thus stimulating cell transcription, galloflavin effects were also studied on this other LDH function.