Rob Zwart

Differentiation and proliferation of respiration-deficient human myoblasts

Replication and transcription of mitochondrial DNA were impaired in dividing human myoblasts exposed to ethidium bromide. MtDNA content decreased linearly per cell division and mitochondrial transcript levels declined rapidly, resulting in respiration-deficiency of the myoblasts. Despite the absence of functional mitochondria the cells remained able to proliferate when grown under specific culture conditions. However, the formation of myotubes was severely impaired in respiration-deficient myoblasts. We conclude that differentiation of myoblasts into myotubes is more dependent on mitochondrial function than proliferation of myoblasts.

The unfolded protein response mediates reversible tau phosphorylation induced by metabolic stress

The unfolded protein response (UPR) is activated in neurodegenerative tauopathies such as Alzheimer’s disease (AD) in close connection with early stages of tau pathology. Metabolic disturbances are strongly associated with increased risk for AD and are a potent inducer of the UPR. Here, we demonstrate that metabolic stress induces the phosphorylation of endogenous tau via activation of the UPR. Strikingly, upon restoration of the metabolic homeostasis, not only the levels of the UPR markers pPERK, pIRE1α and BiP, but also tau phosphorylation are reversed both in cell models as well as in torpor, a physiological hypometabolic model in vivo. Intervention in the UPR using the global UPR inhibitor TUDCA or a specific small-molecule inhibitor of the PERK signaling pathway, inhibits the metabolic stress-induced phosphorylation of tau. These data support a role for UPR-mediated tau phosphorylation as part of an adaptive response to metabolic stress. Failure to restore the metabolic homeostasis will lead to prolonged UPR activation and tau phosphorylation, and may thus contribute to AD pathogenesis. We demonstrate that the UPR is functionally involved in the early stages of tau pathology. Our data indicate that targeting of the UPR may be employed for early intervention in tau-related neurodegenerative diseases.

Liposomes bi-functionalized with phosphatidic acid and an ApoE-derived peptide affect Aβ aggregation features and cross the blood-brain-barrier: implications for therapy of Alzheimer disease.

Targeting amyloid-β peptide (Aβ) within the brain is a strategy actively sought for therapy of Alzheimers disease (AD). We investigated the ability of liposomes bi-functionalized with phosphatidic acid and with a modified ApoE-derived peptide (mApoE-PA-LIP) to affect Aβ aggregation/disaggregation features and to cross in vitro and in vivo the blood-brain barrier (BBB). Surface plasmon resonance showed that bi-functionalized liposomes strongly bind Aβ (kD=0.6 μM), while Thioflavin-T and SDS-PAGE/WB assays show that liposomes inhibit peptide aggregation (70% inhibition after 72 h) and trigger the disaggregation of preformed aggregates (60% decrease after 120 h incubation). Moreover, experiments with dually radiolabelled LIP suggest that bi-functionalization enhances the passage of radioactivity across the BBB either in vitro (permeability=2.5×10(-5) cm/min, 5-fold higher with respect to mono-functionalized liposomes) or in vivo in healthy mice. Taken together, our results suggest that mApoE-PA-LIP are valuable nanodevices with a potential applicability in vivo for the treatment of AD. From the clinical editor: Bi-functionalized liposomes with phosphatidic acid and a modified ApoE-derived peptide were demonstrated to influence Aβ aggregation/disaggregation as a potential treatment in an Alzheimers model. The liposomes were able to cross the blood-brain barrier in vitro and in vivo. Similar liposomes may become clinically valuable nanodevices with a potential applicability for the treatment of Alzheimers disease.

Familial mitochondrial DNA depletion in liver: haplotype analysis of candidate genes

Two sons and one daughter of healthy consanguineous parents presented with fatal hepatic failure in association with severe depletion of mitochondrial (mt)DNA in liver; a third son is healthy. Other published cases of mtDNA depletion concern single members of a family, which excludes the use of haplotype analysis. In the family presented here, the inheritance of the genes for mitochondrial transcription factor A (mtTFA), nuclear respiratory factor 1 (NRF-1), mitochondrial single-stranded DNA-binding protein (mtSSBP), and endonuclease G (EndoG) was studied using microsatellite markers linked to these genes. The inheritance of the gene for mtDNA polymerase (pol γ) was studied using a polymorphic CAG repeat present within the coding region of the gene. EndoG and mtSSBP were excluded, but mtTFA remains a candidate. Pol γ or NRF-1 involvement would be compatible only with autosomal dominant inheritance. Coding sequence analysis of NRF-1 and mtTFA revealed no novel mutations in affected individuals.

Increased Aβ1-42 Production Sensitizes Neuroblastoma Cells for ER Stress Toxicity

Alzheimers disease (AD) is characterized by the aggregation and subsequent deposition of misfolded beta-amyloid (Abeta) peptide. The unfolded protein response (UPR) is activated by misfolded protein stress in the endoplasmic reticulum (ER). In previous studies we demonstrated mild activation of the UPR by extracellularly applied oligomeric but not fibrillar Abeta1-42. In addition, we showed that oligomeric Abeta1-42 is internalized by cells, whereas fibrillar Abeta1-42 remains on the outside of the cell. Inhibition of Abeta uptake specifically inhibits toxicity of Abeta1-42 oligomers, underscoring the toxic potential of intracellular Abeta. Therefore, in the present study, we investigated the connection between intracellularly produced Abeta and the ER stress response, using human neuroblastoma cells overexpressing either wild type APP695 (APPwt) or APP695V717F (APPmut). Both cell lines secrete higher levels of Abeta1-40 and Abeta1-42 compared to the parental line. In addition, APPmut produces more Abeta1-42 than APPwt. Whereas the basal levels of UPR markers are not different, we find augmented UPR induction in response to ER stress in both APP overproducing cell lines compared to the parental cell line, with the strongest UPR activation in APPmut cells. In addition, ER stress toxicity was highest in APPmut cells, strongly suggesting a connection with the production of Abeta1-42. The difference in ER stress mediated toxicity between the APPwt and APPmut cell lines is alleviated by pretreatment with gamma-secretase inhibitor, indicating that it is dependent on Abeta production and in particular on Abeta1-42. Our data indicate that increased Abeta1-42 production sensitizes neuroblastoma cells for ER stress toxicity.

Preferential amplification and phenotypic selection in a population of deleted and wild-type mitochondrial DNA in cultured cells

Abstract In order to study the still poorly understood dynamics of mitochondrial gene segregation, we attempted to alter the percentage of deleted mtDNA (del-mtDNA) over wild-type mtDNA in cell-culture by manipulating respiratory chain capacity. For this purpose, we used a cell-line harbouring a 6-kb mtDNA-deletion which normally was present in 70% of the molecules. The results show that in the presence of low concentrations of doxycycline (DC), an inhibitor of mitochondrial protein synthesis, the average percentage of del-mtDNA in culture steadily declined. After short-term DC treatment most cells still contained del-mtDNA and removal of DC led to a rapid increase in the proportion of del-mtDNA. In contrast, long-term DC treatment rendered del-mtDNA undetectable by Southern analysis, reflecting the complete absence of del-mtDNA in most cells. In this case, del-mtDNA in culture remained at a constant low level after removal of the drug. The results clearly show the importance of phenotypic selection in the segregation of a deleterious mtDNA mutation.

Altered kinetics of cytochrome c oxidase in a patient with severe mitochondrial encephalomyopathy

Deficiency of cytochrome c oxidase activity was established in a girl born to consanguineous parents. She showed symptoms of dysmaturity, generalized hypotonia, myoclonic seizures and progressive respiratory failure, leading to death on the seventh day of life. Structural abnormalities of the central nervous system consisted of severe cerebellar hypoplasia and optic nerve atrophy. Biochemical analysis of a muscle biopsy specimen demonstrated deficiency of cytochrome c oxidase activity. Cultured fibroblasts from this patient also showed a selective decrease in the activity of cytochrome c oxidase, excluding a muscle-specific type of deficiency. Further investigations in cultured fibroblasts revealed that synthesis, assembly and stability of both the mitochondrial and the nuclear subunits of the enzyme were entirely normal. The steady-state concentration of cytochrome c oxidase in the fibroblasts of the patient was also normal, suggesting that the kinetic properties of the enzyme were altered. Analysis of the kinetic parameters of cytochrome c oxidase demonstrated an aberrant interaction between cytochrome c oxidase and its substrate, cytochrome c, most likely because of a mutation in one of the nuclear subunits of the enzyme.

Rab6 is a Modulator of the Unfolded Protein Response: Implications for Alzheimer's Disease

The unfolded protein response (UPR) is a stress response of the endoplasmic reticulum (ER), the first compartment of the secretory pathway. The UPR is activated in non-tangle bearing neurons in Alzheimers disease (AD) brain, indicating it is an early phenomenon. We found that the level of Rab6, implicated in anterograde and retrograde trafficking in the secretory pathway, is increased in brains of AD patients. Rab6 expression, closely correlated with the extent of UPR activation, is not controlled by the UPR. This suggests that Rab6 and UPR activation are both increased in response to early pathogenic changes in AD. Here we demonstrate that Rab6 modulates the UPR, increased levels inhibit whereas decreased levels augment UPR induction. Rab6 is not involved in the initial phase of the UPR; it only affects the UPR after prolonged ER stress. We propose that Rab6 is involved in the recovery from an ER stress insult. The increased Rab6 levels in AD brain in combination with UPR activation suggest that a failure to recover from ER stress may contribute to neurodegeneration in AD. The Rab6 mediated recovery pathway may provide a target to selectively inhibit the destructive pathways of the UPR.

Macrophages and MHC class II positive dendritiform cells in the iris and choroid of the pig

Purpose. Macrophages and dendritic cells (DC) are considered to play an important role in the initiation and propagation of uveitis. Little is known about these cells in the normal pig uveal tract, despite the fact that the pig eye shares many similarities with the human eye and is considered as a suitable species to investigate the pathogenesis of human ocular disease. The aim of this study was to investigate the presence of immunocompetent cells in the uveal tract of the normal pig. Methods. Iris and choroid wholemounts and cryostat sections were obtained from normal pig eyes. Single and double immunohistochemistry was performed by using anti-porcine leukocyte (CD45), anti-porcine macrophage (CD163, CD14), anti-porcine MHC class II (MCA1335), anti-human MHC class II (MCA379G), anti-porcine B lymphocyte (IgM), anti-porcine T lymphocyte (CD6) and anti-porcine granulocyte (MCA1219) monoclonal antibodies. Results. A rich network of dendritiform CD163 positive tissue macrophages was observed in normal pig iris and choroid wholemounts (368 + 84/mm 2, 402 + 97/mm 2, respectively). Approximately 50% of the CD163 positive tissue macrophages in the iris coexpressed MHC class II. Double immunostaining revealed that a small population of the MHC class II positive cells, did not express macrophage markers, and probably represent classical DCs. B lymphocytes and granulocytes were not detected in iris and choroid wholemounts. An occasional T cell could be observed per high power field in iris wholemounts but not in the choroid. Conclusions. The present study reveals that the normal pig uveal tract contains a rich network of tissue macrophages and MHC class II positive dendritiform cells. At least three populations could be distinguished: MHC class II positive and negative tissue macrophages and MHC class II + dendritiform cells lacking tissue macrophage markers.

Disturbed Ca2+ Homeostasis Increases Glutaminyl Cyclase Expression; Connecting Two Early Pathogenic Events in Alzheimer’s Disease In Vitro

A major neuropathological hallmark of Alzheimer’s disease (AD) is the deposition of aggregated β amyloid (Aβ) peptide in the senile plaques. Aβ is a peptide of 38–43 amino acids and its accumulation and aggregation plays a key role early in the disease. A large fraction of β amyloid is N-terminally truncated rendering a glutamine that can subsequently be cyclized into pyroglutamate (pE). This makes the peptide more resistant to proteases, more prone to aggregation and increases its neurotoxicity. The enzyme glutaminyl cyclase (QC) catalyzes this conversion of glutamine to pE. In brains of AD patients, the expression of QC is increased in the earliest stages of pathology, which may be an important event in the pathogenesis. In this study we aimed to investigate the regulatory mechanism underlying the upregulation of QC expression in AD. Using differentiated SK-N-SH as a neuronal cell model, we found that neither the presence of Aβ peptides nor the unfolded protein response, two early events in AD, leads to increased QC levels. In contrast, we demonstrated increased QC mRNA levels and enzyme activity in response to another pathogenic factor in AD, perturbed intracellular Ca2+ homeostasis. The QC promoter contains a putative binding site for the Ca2+ dependent transcription factors c-fos and c-jun. C-fos and c-jun are induced by the same Ca2+-related stimuli as QC and their upregulation precedes QC expression. We show that in the human brain QC is predominantly expressed by neurons. Interestingly, the Ca2+- dependent regulation of both c-fos and QC is not observed in non-neuronal cells. Our results indicate that perturbed Ca2+ homeostasis results in upregulation of QC selectively in neuronal cells via Ca2+- dependent transcription factors. This suggests that disruption of Ca2+ homeostasis may contribute to the formation of the neurotoxic pE Aβ peptides in Alzheimer’s disease.