The role of dynamin-related protein 1 in cancer growth: a promising therapeutic target?

Mitochondrial functions are altered in many human diseases including cancer. Development of mitochondria-targeted therapies, either through restoring normal mitochondrial function or promoting mitochondrial-induced cell death, is one of the attractive strategies to improve the outcome of cancer treatment. Recent advances have revealed the important functional involvement of mitochondrial dynamics in cancer biology. Dynamin-related protein 1 (Drp1), a member of the dynamin family of GTPases required for mitochondrial fission, has been found upregulated in certain types of cancers, such as lung and breast cancers. In addition, the roles of Drp1 in cell cycle progression, genome instability, cell migration and apoptosis in cancer cells have also been recently uncovered. These findings raise the possibility of targeting Drp1-mediated mitochondrial fission as an effective therapy for treating cancer. This article explores the function of Drp1 in cancer cells and discusses the theoretical basis for the development of potential targeted therapy.     

Mitochondrial DNA haplogroup associated with sperm motility in the Han population

In this study, we aimed to determine whether the main mitochondrial DNA （mtDNA） haplogroups of the Han people have an impact on spermatozoa motility, We recruited 312 men who were consecutively admitted to two affiliated hospitals of College of Medicine, Zhejiang University from May 2011 to April 2012 as part of fertility investigations. Semen and whole blood samples were collected from the men. We determined the mtDNA haplogroups by analysing the sequences of mtDNA hypervariable segment I and testing diagnostic polymorphisms in the mtDNA coding region with DNA probes, No significant differences were found in the clinical characteristics of the mtDNA haplogroup R and non-R （P〉0.05）. Our results suggest that mtDNA haplogroup R is a strong independent predictor of sperm motility in the Han population, conferring a 2.97-fold （95% confidence interval： 1.74-4.48, P〈0.001） decreased chance of asthenozoospermia compared with those without haplogroup R.     

Role for cytoplasmic nucleotide hydrolysis in hepatic function and protein synthesis

Nucleotide hydrolysis is essential for many aspects of cellular function. In the case of 3′,5′-bisphosphorylated nucleotides, mammals possess two related 3′-nucleotidases, Golgi-resident 3′-phosphoadenosine 5′-phosphate (PAP) phosphatase (gPAPP) and Bisphosphate 3′-nucleotidase 1 (Bpnt1). gPAPP and Bpnt1 localize to distinct subcellular compartments and are members of a conserved family of metal-dependent lithium-sensitive enzymes. Although recent studies have demonstrated the importance of gPAPP for proper skeletal development in mice and humans, the role of Bpnt1 in mammals remains largely unknown. Here we report that mice deficient for Bpnt1 do not exhibit skeletal defects but instead develop severe liver pathologies, including hypoproteinemia, hepatocellular damage, and in severe cases, frank whole-body edema and death. Accompanying these phenotypes, we observed tissue-specific elevations of the substrate PAP, up to 50-fold in liver, repressed translation, and aberrant nucleolar architecture. Remarkably, the phenotypes of the Bpnt1 knockout are rescued by generating a double mutant mouse deficient for both PAP synthesis and hydrolysis, consistent with a mechanism in which PAP accumulation is toxic to tissue function independent of sulfation. Overall, our study defines a role for Bpnt1 in mammalian physiology and provides mechanistic insights into the importance of sulfur assimilation and cytoplasmic PAP hydrolysis to normal liver function.     

Induction of apoptosis by heat and γ-radiation in a human lymphoid cell line; role of mitochondrial changes and caspase activation

Purpose: The aim of the study was to investigate the molecular mechanisms involved in apoptosis of human promyelocytic cells (HL60) induced by hyperthermia and to compare this to radiation-induced apoptosis as a reference model.

Materials and methods: Apoptosis of HL60 cells was induced by heat-treatment (43°C during 1?h) or by γ-radiation (8?Gy) and followed at increasing time periods after treatment with Annexin V binding to phosphatidylserine (PS). The transition of the mitochondrial membrane potential (Δψ_m) was estimated by the extent of mitochondrial JC-1 uptake. Bcl-2 and Bax protein expression levels were monitored using fluorescent-labelled antibodies. Caspase activation was studied using a fluorochrome-labelled pan-caspase inhibitor (FLICA), which also allowed one to study the kinetics of the apoptotic cascade.

Results: After heat-treatment or irradiation of HL60 cells, a decreased Δψ_m as well as PS membrane expression were detectable after 8?h. Bcl-2 and Bax protein expression levels were decreased and increased, respectively, 1?h after heat-treatment or irradiation. The apoptotic rate of HL60 cells, as measured by the FLICA binding, was faster with heat-treatment as compared to γ-irradiation. Addition of a pan-caspase inhibitor prevented PS externalization after heat-treatment but not after irradiation. The presence of a pan-caspase inhibitor did not influence the decrease of Δψ_m both after heat-treatment and γ-irradiation. However, the addition of the specific caspase-2 inhibitor zVDVAD-fmk prevented the mitochondrial breakdown after heat-treatment. Inhibition of caspase-2 had no effect on the γ-irradiation induced apoptosis.

Conclusion: These results suggest that the commitment to apoptosis in HL60 cells after heat-treatment is started by mitochondrial membrane transition involving the Bcl-2 family members and is mainly executed in a caspase-dependent pathway. The results suggest that caspase-2 plays a key role in the heat-induced apoptosis.     

Inositol hexakisphosphate kinase-2 determines cellular energy dynamics by regulating creatine kinase-B

Inositol hexakisphosphate kinases (IP6Ks) regulate various biological processes. IP6Ks convert IP6 to pyrophosphates such as diphosphoinositol pentakisphosphate (IP7) and bis-diphosphoinositol tetrakisphosphate (IP8). IP7 is produced in mammals by a family of inositol hexakisphosphate kinases, IP6K1, IP6K2, and IP6K3, which have distinct biological functions. The inositol hexakisphosphate kinase 2 (IP6K2) controls cellular apoptosis. To explore roles for IP6K2 in brain function, we elucidated its protein interactome in mouse brain revealing a robust association of IP6K2 with creatine kinase-B (CK-B), a key enzyme in energy homeostasis. Cerebella of IP6K2-deleted mice (IP6K2-knockout [KO]) produced less phosphocreatine and ATP and generated higher levels of reactive oxygen species and protein oxidative damage. In IP6K2-KO mice, mitochondrial dysfunction was associated with impaired expression of the cytochrome-c1 subunit of complex III of the electron transport chain. We reversed some of these effects by combined treatment with N-acetylcysteine and phosphocreatine. These findings establish a role for IP6K2–CK-B interaction in energy homeostasis associated with neuroprotection.

Inositol pyrophosphates are versatile messenger molecules that mediate a variety of cellular functions, including cell growth, apoptosis, endocytosis, and cell differentiation. The most extensively studied inositol pyrophosphate, diphosphoinositol pentakisphosphate (IP7), displays a 5′-diphosphate (1, 2). IP7 is generated in mammals by a family of inositol hexakisphosphate kinases (IP6Ks) (3, 4). IP6Ks exists in three isoforms: IP6K1, IP6K2, and IP6K3. Inositol hexakisphosphate kinase-2 (IP6K2) sensitizes cells to apoptosis (5, 6). Mice with targeted deletion of IP6K2 display an increased incidence of aero-digestive tract carcinoma (7). Cell survival associated with heat shock protein 90 also involves IP6K2 (8, 9).We previously reported a major role for IP6K2 in the disposition of cerebellar granule cells as well as Purkinje cell morphology and motor coordination. The influence of IP6K2 upon cerebellar disposition involved protein 4.1N, both of which were highly expressed in cerebellar granule cells (10).To further assess the functions of IP6K2 in the brain, we explored its binding partners using coimmunoprecipitation and tandem liquid chromatography mass spectrometry (LC-MS/MS). Here, we report that IP6K2 robustly interacts with creatine kinase-B (CK-B), which regulates energy homeostasis of cells and exists in two forms, brain type (CK-B) and muscle type (CK-M). CK catalyzes the reversible transfer of the phosphate group of phosphocreatine to ADP to yield ATP (11, 12). A functional interplay between mitochondrial and cytosolic isoforms of CK regulates cellular energy homeostasis. Cytosolic CK rephosphorylates locally produced free ADP and increases creatine globally, while the mitochondrial enzyme catalyzes the conversion of creatine to phosphocreatine utilizing mitochondrial ATP (13–15).Here, we show that IP6K2 loss leads to decreased CK-B expression, reduced ATP levels, and diminished mitochondrial activity associated with increased oxidative stress. About 80 to 90% of ATP is generated in the mitochondria by oxidative phosphorylation, and diminished ATP levels are the immediate effect of mitochondrial dysfunction. Loss of IP6K2 and CK-B reflects the suppression of the mitochondrial cytochrome c1 expression, a component of complex III of the mitochondrial electron transport chain. In the present study, we report a physiologic association of CK-B and IP6K2, whose disruption impacts mitochondrial functions.Dendritic morphogenesis was reduced in IP6K2-deficient neurons and was rescued by restoring normal levels of ATP. These observations reveal an essential role of IP6K2 in the energy production of the brain. Our findings indicate that IP6K2 is a key regulator of mitochondrial homeostasis which promotes neuroprotection.     

Effect of experimental thyrotoxicosis on oxidative phosphorylation in rat liver, kidney and brain mitochondria

Coupled phosphorylation was examined in liver, kidney and brain mitochondria from rats made thyrotoxic by injecting repeated doses of triiodothyronine. Liver and kidney mitochondria were maximally affected under these conditions, whereas effects on brain mitochondria were marginal. State-3 respiration rates with succinate decreased considerably in all the tissues, whereas glutamate oxidation increased in liver, but decreased in kidney and brain mitochondria. Oxidation rates of beta-hydroxybutyrate decreased in kidney and brain mitochondria but were not significantly affected in liver mitochondria. Oxidation of ascorbate + TMPD was not affected. State-4 respiration rates increased in general with all the substrates resulting in lowering of the RCI. The ADP/O ratios decreased in a site-specific manner in the mitochondria from the three tissues. The content of cytochrome b decreased in all three tissues, whereas the content of cytochrome c + c1 increased in liver and kidney but decreased in brain. The content of cytochrome a, however, was not significantly affected. Basal and Mg2+-stimulated ATPase activities increased in mitochondria of liver and kidney but not in those of brain; total ATPase activities, however, were not altered. The results imply that excessive levels of thyroid hormones over normal in the serum can lead to impairment of mitochondrial energy metabolism in a tissue-specific manner.     

Mechanisms of Ammonia-Induced Astrocyte Swelling

Astrocyte swelling represents the major factor responsible for the brain edema associated with fulminant hepatic failure (FHF). The edema may be of such magnitude as to increase intracranial pressure leading to brain herniation and death. Of the various agents implicated in the generation of astrocyte swelling, ammonia has had the greatest amount of experimental support. This article reviews mechanisms of ammonia neurotoxicity that contribute to astrocyte swelling. These include oxidative stress and the mitochondrial permeability transition (MPT). The involvement of glutamine in the production of cell swelling will be highlighted. Evidence will be provided that glutamine induces oxidative stress as well as the MPT, and that these events are critical in the development of astrocyte swelling in hyperammonemia.     

Prolonged cardiac arrest and resuscitation in dogs: brain mitochondrial function with different artificial perfusion methods

Clinical techniques for artificial perfusion have not previously been examined directly for their effects on brain high-energy metabolism. Our study involved 24 large mongrel dogs that were anesthetized, instrumented for central venous intravenous access, and subjected to craniotomy to expose the dura and underlying parietal cortex. The animals were divided into the following six experimental groups of four animals each: nonischemic controls; 15-minute cardiac arrest without resuscitation; 45-minute cardiac arrest without resuscitation; 15-minute cardiac arrest plus 30 minutes resuscitation with conventional cardiopulmonary resuscitation (CPR); 15-minute cardiac arrest plus 30 minutes resuscitation with interposed abdominal compression (IAC) CPR; and 15-minute cardiac arrest plus 30 minutes resuscitation with internal cardiac massage. Cardiac arrest was induced by central venous injection of KCl 0.6 mEq/kg, and it was confirmed by continuous ECG monitoring. The three active resuscitation models included administration of NaHCO3 and epinephrine, but no attempt was made to restart the heart by defibrillation during resuscitation. At the indicated time in each group, a 4- to 5-g sample of brain was removed through the craniotomy, immediately cooled to 0 C and processed for isolation of mitochondria. The mitochondria were studied for their content of superoxide dismutase and for quantitative oxygen consumption with glutamate/malate substrate during resting and ADP-stimulated respiration. Our results show a significant drop in brain mitochondrial superoxide dismutase activity during the first 15 minutes of cardiac arrest. There is minimal injury to brain mitochondrial oxygen consumption during both 15 and 45 minutes of complete ischemia.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular diagnosis of coenzyme Q10 deficiency: an update

Introduction: Coenzyme Q₁₀ (CoQ) deficiency syndromes comprise a growing number of genetic disorders. While primary CoQ deficiency syndromes are rare diseases, secondary deficiencies have been related to both genetic and environmental conditions, which are the main causes of biochemical CoQ deficiency. The diagnosis is the essential first step for planning future treatment strategies, as the potential treatability of CoQ deficiency is the most critical issue for the patients.

Areas covered: While the quickest and most effective tool to define a CoQ-deficient status is its biochemical determination in biological fluids or tissues, this quantification does not provide a definite diagnosis of a CoQ-deficient status nor insight about the genetic etiology of the disease. The different laboratory tests to check for CoQ deficiency are evaluated in order to choose the best diagnostic pathway for the patient.

Expert commentary: New insights are being discovered about the implication of new proteins in the intricate CoQ biosynthetic pathway. These insights reinforce the idea that next generation sequencing diagnostic strategies are the unique alternative in terms of rapid and accurate molecular diagnosis of CoQ deficiency.