Domenico Boffoli

Hepatitis C virus protein expression causes calcium‐mediated mitochondrial bioenergetic dysfunction and nitro‐oxidative stress

Hepatitis C virus (HCV) infection induces a state of oxidative stress that is more pronounced than that in many other inflammatory diseases. In this study we used well‐characterized cell lines inducibly expressing the entire HCV open‐reading frame to investigate the impact of viral protein expression on cell bioenergetics. It was shown that HCV protein expression has a profound effect on cell oxidative metabolism, with specific inhibition of complex I activity, depression of mitochondrial membrane potential and oxidative phosphorylation coupling efficiency, increased production of reactive oxygen and nitrogen species, as well as loss of the Pasteur effect. Importantly, all these effects were causally related to mitochondrial calcium overload, as inhibition of mitochondrial calcium uptake completely reversed the observed bioenergetic alterations. Conclusion: Expression of HCV proteins causes deregulation of mitochondrial calcium homeostasis. This event occurs upstream of further mitochondrial dysfunction, leading to alterations in the bioenergetic balance and nitro‐oxidative stress. These observations provide new insights into the pathogenesis of hepatitis C and may offer new opportunities for therapeutic intervention. (HEPATOLOGY 2007.)

Mitochondrial Respiratory Dysfunction in Familiar Parkinsonism Associated with PINK1 Mutation

In the present study mitochondrial respiratory function of fibroblasts from a patient affected by early-onset Parkinsonism carrying the homozygous W437X nonsense mutation in the PINK1 gene has been thoroughly characterized. When compared with normal fibroblasts, the patient’s fibroblast mitochondria exhibited a lower respiratory activity and a decreased respiratory control ratio with cellular ATP supply relying mainly on enhanced glycolytic production. The quantity, specific activity and subunit pattern of the oxidative phosphorylation complexes were normal. However, a significant decrease of the cellular cytochrome c content was observed and this correlated with a reduced cytochrome c oxidase in situ-activity. Measurement of ROS revealed in mitochondria of the patient’s fibroblasts enhanced O2•− and H2O2 production abrogated by inhibition of complex I. No change in the glutathione-based redox buffering was, however, observed.

Control by cytochrome c oxidase of the cellular oxidative phosphorylation system depends on the mitochondrial energy state

Recent measurements of the flux control exerted by cytochrome c oxidase on the respiratory activity in intact cells have led to a re-appraisal of its regulatory function. We have further extended this in vivo study in the framework of the Metabolic Control Analysis and evaluated the impact of the mitochondrial transmembrane electrochemical potential (Deltamu(H+)) on the control strength of the oxidase. The results indicate that, under conditions mimicking the mitochondrial State 4 of respiration, both the flux control coefficient and the threshold value of cytochrome oxidase are modified with respect to the uncoupled condition. The results obtained are consistent with a model based on changes in the assembly state of the oxidative phosphorylation enzyme complexes and possible implications in the understanding of exercise-intolerance of human neuromuscular degenerative diseases are discussed.

The hypoxia-inducible factor is stabilized in circulating hematopoietic stem cells under normoxic conditions

The hypoxia‐inducible factor (HIF) transcriptional system enables cell adaptation to limited O2 availability, transducing this signal into patho‐physiological responses such as angiogenesis, erythropoiesis, vasomotor control, and altered energy metabolism, as well as cell survival decisions. However, other factors beyond hypoxia are known to activate this pleiotropic transcription factor. The aim of this study was to characterize HIF in human hematopoietic stem cells (HSCs) and evidence is provided that granulocyte colony stimulating factor‐mobilized CD34+‐ and CD133+‐HSCs express a stabilized cytoplasmic form of HIF‐1α under normoxic conditions. It is shown that HIF‐1α stabilization correlates with down‐regulation of the tumour suppressor von Hippel‐Lindau protein (pVHL) and is positively controlled by NADPH‐oxidase‐dependent production of reactive oxygen species, indicating a specific O2‐independent post‐transcriptional control of HIF in mobilized HSCs. This novel finding is discussed in the context of the proposed role of HIF as a mediator of progenitor cell recruitment to injured ischemic tissues and/or in the control of the maintenance of the undifferentiated state.

HCV infection induces mitochondrial bioenergetic unbalance: Causes and effects

Cells infected by the hepatitis C virus (HCV) are characterized by endoplasmic reticulum stress, deregulation of the calcium homeostasis and unbalance of the oxido-reduction state. In this context, mitochondrial dysfunction proved to be involved and is thought to contribute to the outcome of the HCV-related disease. Here, we propose a temporal sequence of events in the HCV-infected cell whereby the primary alteration consists of a release of Ca(2+) from the endoplasmic reticulum, followed by uptake into mitochondria. This causes successive mitochondrial alterations comprising generation of reactive oxygen and nitrogen species and impairment of the oxidative phosphorylation. A progressive adaptive response results in an enhancement of the glycolytic metabolism sustained by up-regulation of the hypoxia inducible factor. Pathogenetic implications of the model are discussed.

cAMP controls oxygen metabolism in mammalian cells

The impact of cAMP on ROS‐balance in human and mammalian cell cultures was studied. cAMP reduced accumulation of ROS induced by serum‐limitation, under conditions in which there was no significant change in the activity of scavenger systems. This effect was associated with cAMP‐dependent activation of the NADH‐ubiquinone oxidoreductase activity of complex I. In fibroblasts from a patient a genetic defect in the 75 kDa FeS‐protein subunit of complex I resulted in inhibition of the activity of the complex and enhanced ROS production, which were reversed by cAMP. A missense genetic defect in the NDUFS4 subunit, putative substrate of PKA, suppressed, on the other hand, the activity of the complex and prevented ROS production.

Coexistence of mutations in PINK1 and mitochondrial DNA in early onset parkinsonism

Aims and background: Various genes have been identified for monogenic disorders resembling Parkinson’s disease. The products of some of these genes are associated with mitochondria and have been implicated in cellular protection against oxidative damage. In the present study we analysed fibroblasts from a patient carrying the homozygous mutation p.W437X in the PTEN-induced kinase 1 (PINK1), which manifested a very early onset parkinsonism. Results: Patient’s fibroblasts did not show variation in the mtDNA copy number or in the expression of the oxidative phosphorylation complexes. Sequence analysis of the patient’s mtDNA presented two new missense mutations in the ND5 (m.12397A>G, p.T21A) and ND6 (m. 14319T>C, p.N119D) genes coding for two subunits of complex I. The two mutations were homoplasmic in both the patient and the patient’s mother. Patient’s fibroblasts resulted in enhanced constitutive production of the superoxide anion radical that was abrogated by inhibitor of the complex I. Moreover enzyme kinetic analysis of the NADH:ubiquinone oxidoreductase showed changes in the substrates affinity. Conclusion: To our knowledge, this is the first report showing co-segregation of a Parkinson’s disease related nuclear gene mutation with mtDNA mutation(s). Our observation might shed light on the clinical heterogeneity of the hereditary cases of Parkinson’s disease, highlighting the hitherto unappreciated impact of coexisting mtDNA mutations in determining the development and the clinical course of the disease.

Topological organization of NADPH-oxidase in haematopoietic stem cell membrane: preliminary study by fluorescence near-field optical microscopy.

The aim of this study was to characterize the local distribution and organization of the plasma membrane NADPH‐oxidase (NOX) in human haematopoietic stem cell (HSC) by means of the fluorescence scanning near‐field optical microscopy approach. The presence of NOX in haematopoietic stem cells is thought to have a functional role as O2 sensor and/or as low‐level reactive oxygen species (ROS) producer to be used as redox messenger for controlling cell growth and differentiation. Given the harmful potential of ROS, a fine‐tuning of NOX activity is needed. The high resolution imaging of haematopoietic stem cell membrane obtained in this study combined with the immunodetection of NOX indicates for this the occurrence of a cluster‐organized structure. These membrane ‘rafts’‐like micro‐compartments may constitute localized protein aggregates whereby the assembly/activation of the NOX components are functionally integrated with upstream factors constituting signal‐transduction platforms.

Native LDL‐induced oxidative stress in human proximal tubular cells: multiple players involved

Dyslipidemia is a well‐established condition proved to accelerate the progression of chronic kidney disease leading to tubulo‐interstitial injury. However, the molecular aspects of the dyslipidemia‐induced renal damage have not been fully clarified and in particular the role played by low‐density lipoproteins (LDLs). This study aimed to examine the effects of native non‐oxidized LDL on cellular oxidative metabolism in cultured human proximal tubular cells. By means of confocal microscopy imaging combined to respirometric and enzymatic assays it is shown that purified native LDL caused a marked increase of cellular reactive oxygen species (ROS) production, which was mediated by activation of NADPH oxidase(s) and by mitochondrial dysfunction by means of a ROS‐induced ROS release mechanism. The LDL‐dependent mitochondrial alterations comprised inhibition of the respiratory chain activity, enhanced ROS production, uncoupling of the oxidative phosphorylation efficiency, collapse of the mtΔΨ, increased Ca2+ uptake and loss of cytochrome c. All the above LDL‐induced effects were completely abrogated by chelating extracellular Ca2+ as well as by inhibition of the Ca2+‐activated cytoplas‐mic phospholipase A2, NADPH oxidase and mitochondrial permeability transition. We propose a mechanicistic model whereby the LDL‐induced intracellular redox unbalance is triggered by a Ca2+ inward flux‐dependent commencement of cPLA2 followed by activation of a lipid‐ and ROS‐based cross‐talking signalling pathway. This involves first oxidants production via the plasmamembrane NADPH oxidase and then propagates downstream to mitochondria eliciting redox‐ and Ca2+‐dependent dysfunctions leading to cell‐harming conditions. These findings may help to clarify the mechanism of dyslipidemia‐induced renal damage and suggest new potential targets for specific therapeutic strategies to prevent oxidative stress implicated in kidney diseases.

MtDNA mutation associated with mitochondrial dysfunction in megakaryoblastic leukaemic cells

MtDNA mutation associated with mitochondrial dysfunction in megakaryoblastic leukaemic cells