The reciprocal roles of PARK2 and mitofusins in mitophagy and mitochondrial spheroid formation

Mitochondrial homeostasis is critical to cellular homeostasis, and mitophagy is an important mechanism to eliminate mitochondria that are superfluous or damaged. Multiple events can be involved in the recognition of mitochondria by the phagophore, and the key one is the priming of the mitochondria with specific molecular signatures. PARK2/Parkin is an E3 ligase that can be recruited to depolarized mitochondria and is required for mitophagy caused by respiration uncoupling. PARK2 induces ubiquitination of mitochondrial outer membrane proteins, which are subsequently degraded by the proteasome. Why these PARK2-mediated priming events are necessary for mitophagy to occur is not clear. We propose that they are needed to prevent a default pathway that would be inhibitory to mitophagy. In the default pathway depolarized and fragmented mitochondria undergo a dramatic three-dimensional conformational change to become mitochondrial spheroids. This transformation requires mitofusins; however, PARK2 inhibits this process by causing mitofusin ubiquitination and degradation. The spherical transformation may prevent recognition of the damaged mitochondria by the autophagosome, and PARK2 ensures that no such transformation occurs in order to promote mitophagy. Whether the formed mitochondrial spheroids functionally represent an alternative mitigation to mitophagy or an adverse consequence in the absence of PARK2 has yet to be determined.     

Dynamin 1-like-dependent mitochondrial fission initiates overactive mitophagy in the hepatotoxicity of cadmium

How cadmium (Cd) induces mitochondrial loss in the context of its hepatotoxic effects remains enigmatic. The purpose of the study was to investigate whether mitophagy contributes to mitochondrial loss in cadmium-induced hepatotoxicity and to determine the potential mechanism. In normal human liver L02 cells, we observed that Cd treatment led to a significant increase in LC3-II formation, the number of GFP-LC3 puncta and lysosomal colocalization with mitochondria. These results were associated with mitochondrial loss and bioenergetic deficit. Additionally, the abrogation of excessive mitophagy by ATG5 siRNA treatment efficiently suppressed the mitochondrial loss and cytotoxicity of Cd. Before overactivating mitophagy, Cd induced excessive mitochondrial fragmentation as a result of increasing dynamin 1-like (DNM1L) expression and enhancing the DNM1L mitochondrial translocation. Moreover, reversing the excessive mitochondrial fragmentation via the administration of DNM1L siRNA significantly inhibited the observed overactivation of mitophagy in Cd-induced hepatotoxicity. Notably, the selective DNM1L inhibitor Mdivi-1 blocked abnormal mitophagy and subsequently ameliorated Cd-induced hepatotoxicity in vivo. Together, our data indicated that Cd induces mitochondrial loss via the overactivation of mitophagy following DNM1L-dependent mitochondrial fragmentation. The balanced activity of DNM1L and mitophagy signaling may be a potential therapeutic approach to treat Cd-induced hepatotoxicity.     

Complete mitochondrial genomes offer insights into the evolutionary relationships and comparative genetic diversity of New Zealand’s iconic kiwi (Apteryx spp.)

ABSTRACT

Kiwis (Apterygidae) are an enigmatic family of flightless birds endemic to New Zealand. Apterygidae is made up of a single genus, Apteryx with five species, four of which are characterised as at risk of greater by the New Zealand Department of Conservation. These five species are further separated into two morphologically and genetically distinguishable clades, containing A.haastii, and A.owenii in one and A.rowi, A.mantelli, and A.australis in the other. We reconstructed 17 kiwi mitochondrial genomes from previously published genomic data, nine from A.rowi and eight from A.owenii. Mitochondrial diversity analyses uncovered low levels of genetic diversity consistent with their reduced ranges and conservation concern. We further used one of the assembled A.rowi mitochondrial genomes together with mitochondrial genomes from A.haastii, A.owenii, A.mantelli, and several other individuals from Palaeognathae to estimate the within and between clade divergence times of kiwis. Our study exemplifies how available published data can be used in novel ways to provide new and complementary evolutionary insights to previous studies.     

Polymerase γ efficiently replicates through many natural template barriers but stalls at the HSP1 quadruplex

Faithful replication of the mitochondrial genome is carried out by a set of key nuclear-encoded proteins. DNA polymerase γ is a core component of the mtDNA replisome and the only replicative DNA polymerase localized to mitochondria. The asynchronous mechanism of mtDNA replication predicts that the replication machinery encounters dsDNA and unique physical barriers such as structured genes, G-quadruplexes, and other obstacles. In vitro experiments here provide evidence that the polymerase γ heterotrimer is well-adapted to efficiently synthesize DNA, despite the presence of many naturally occurring roadblocks. However, we identified a specific G-quadruplex–forming sequence at the heavy-strand promoter (HSP1) that has the potential to cause significant stalling of mtDNA replication. Furthermore, this structured region of DNA corresponds to the break site for a large (3,895 bp) deletion observed in mitochondrial disease patients. The presence of this deletion in humans correlates with UV exposure, and we have found that efficiency of polymerase γ DNA synthesis is reduced after this quadruplex is exposed to UV in vitro.     

Protective effects of irisin on hypoxia-reoxygenation injury in hyperglycemia-treated cardiomyocytes: Role of AMPK pathway and mitochondrial protection

Recent evidence has verified the cardioprotective actions of irisin in different diseases models. However, the beneficial action of irisin on hypoxia-reoxygenation (HR) injury under high glucose stress has not been described. Herein our research investigated the influence of irisin on HR-triggered cardiomyocyte death under high glucose stress. HR model was established in vitro under high glucose treatment. The results illuminated that HR injury augmented apoptotic ratio of cardiomyocyte under high glucose stress; this effect could be abolished by irisin via modulating mitochondrial function. Irisin treatment attenuated cellular redox stress, improved cellular ATP biogenetics, sustained mitochondria potential, and impaired mitochondrion-related cell death. At the molecular levels, irisin treatment activated the 5′-adenosine monophosphate-activated protein kinase (AMPK) pathway and the latter protected cardiomyocyte and mitochondria against HR injury under high glucose stress. Altogether, our results indicated a novel role of irisin in HR-treated cardiomyocyte under high glucose stress. Irisin-activated AMPK pathway and the latter sustained cardiomyocyte viability and mitochondrial function.     

Dementia from the ABCD1 mutation c.1415-1416delAG in a female carrier

Objectives

Progressive dementia is a rare phenotypic feature of female X-ALD carriers. Even rarer is the additional presence of further risk factors for dementia, such as diabetes, hypothyroidism, and hepatopathy. We report a unique female X-ALD carrier presenting with severe, progressive dementia, paraspasticity, sphincteric dysfunction, and multisystem disease.

Case report

A 79 years-old female with a history of strumectomy, diabetes, hepatopathy, hypothyroidism, arterial hypertension, hiatal hernia, left retinal ablation, ovariectomy, hysterectomy, osteoporosis, bilateral hip endoprosthesis, and neurogenic bladder dysfunction developed slowly progressive cognitive decline since age of 77 years. She had been identified as a female carrier of X-ALD in 12/2010 upon a family screening. At age of 79 years she presented with severe dementia, anxiety, unsteadiness, helplessness, hypertelorism, exaggerated patella tendon reflexes, reduced Achilles tendon reflexes, club feet, contractures of the ankles, the knees, and the hips, and the inability to stay or walk. Cerebral CT showed diffuse atrophy, demyelination periventricularly, small lacunas in the basal ganglia, and small calcifications of the basal ganglia and the temporal lobe on the right side. Differential diagnoses of dementia were considered but were all excluded upon the clinical presentation, blood chemical investigations, imaging studies, and the pattern of neuropsychological deficits.

Conclusions

With progression of the disease manifesting X-ALD carriers may develop progressive severe dementia, severe paraspasticity, and sphincteric dysfunction. Female carriership of X-ALD can be a differential diagnosis of dementia.