ARL2 and BART Enter Mitochondria and Bind the Adenine Nucleotide Transporter

The ADP-ribosylation factor-like 2 (ARL2) GTPase and its binding partner binder of ARL2 (BART) are ubiquitously expressed in rodent and human tissues and are most abundant in brain. Both ARL2 and BART are predominantly cytosolic, but a pool of each was found associated with mitochondria in a protease-resistant form. ARL2 was found to lack covalent N-myristoylation, present on all other members of the ARF family, thereby preserving the N-terminal amphipathic alpha-helix as a potential mitochondrial import sequence. An overlay assay was developed to identify binding partners for the BART.ARL2.GTP complex and revealed a specific interaction with a protein in bovine brain mitochondria. Purification and partial microsequencing identified the protein as an adenine nucleotide transporter (ANT). The overlay assay was performed on mitochondria isolated from five different tissues from either wild-type or transgenic mice deleted for ANT1. Results confirmed that ANT1 is the predominant binding partner for the BART.ARL2.GTP complex and that the structurally homologous ANT2 protein does not bind the complex. Cardiac and skeletal muscle mitochondria from ant1(-)/ant1(-) mice had increased levels of ARL2, relative to that seen in mitochondria from wild-type animals. We conclude that the amount of ARL2 in mitochondria is subject to regulation via an ANT1-sensitive pathway in muscle tissues.     

卵母细胞成熟过程中线粒体的变化

卵子成熟是一个复杂的过程,细胞核成熟和细胞质成熟必须和谐的统一在一起,才能保证卵子的正常受精和进一步的发育。作为细胞质内最重要的细胞器,线粒体的分布在卵子成熟过程中出现了显著变化。同时其产生的ATP是卵子、受精卵以及胚胎主要的能量来源。因此,对卵子成熟过程中线粒体的分布和功能变化的研究,有利于进一步了解生殖生理,并为解决辅助生育技术中所面临的难题提供新的思路。     

nHAP对大鼠肝线粒体的生物活性作用

为了探讨羟基磷灰石纳米粒子(nHAP)对大鼠肝线粒体生物活性的影响,将nHAP直接作用于线粒体,在不同浓度和时间下测定线粒体标志酶琥珀酸脱氢酶(SDH)比活性,并与对照组进行比较。结果显示,当nHAP中水含量在10%以下时,线粒体生物活性未发现改变;当nHAP浓度递增时,在等时间段内,对线粒体SDH比活性呈逐步抑制作用;在不等时间段内,nHAP对线粒体SDH比活性的抑制作用与对照组相比较差异有显著性(p<0.05)。因此,nHAP对线粒体SDH比活性的抑制有浓度和时间的依赖性。     

The Effects of Atractyloside and Bongkrekic Acid on Jerusalem Artichoke Mitochondria in Relation to Adenine Nucleotide Translocation

The translocation of ADP and ATP across the inner membrane ofJerusalem artichoke mitochondria is demonstrated. Atractyloside,a competitive inhibitor of the adenine nucleotide translocatorof mammalian mitochondria, is without effect in artichoke mitochondriawhen added at concentrations normally inhibitory in the animalsystem. Bongkrekic acid, a noncompetitive inhibitor, inhibitsthe adenine nucleotide-dependent processes of artichoke andmammalian mitochondria at similar concentrations. The effectsof atractyloside and bongkrekic acid in relation to adeninenucleotide translocation are discussed.     

Study of DNA-Binding Proteins of Rat Liver Mitochondria

Acid-soluble proteins able to form DNA-protein complexes in the presence of physiological concentration of NaCl were isolated from rat liver mitochondria. Electrophoretic analysis of these proteins in 15% polyacrylamide gel showed that mitochondrial acid-soluble proteins include of approximately 20 polypeptides with molecular weight of 10–120 kDa. The fraction of acid-soluble proteins can be separated into basic and acidic proteins by chromatography on DEAE cellulose. Some of acidic proteins are tightly bound to the basic proteins and can be separated from them in the presence of 5 mM dithiothreitol. It is discovered that the fraction of acidic proteins contains proteases (including DNA-activated ones), which cleave different polypeptides of the basic proteins with different efficiency. Possibly, mitochondrial DNA-binding proteins and DNA-activated proteases are involved in the regulation of structural organization and functional activity of mitochondrial DNA.     

大鼠肝线粒体中的脂肪酸分析

用双 2 乙基己基酚酞酸酯 (DEHP)诱导大鼠肝过氧化物酶体增殖 ,然后用蔗糖密度梯度离心法分离大鼠肝线粒体 ,用毛细管气相色谱法测定肝线粒体中的脂肪酸含量。测定结果 :所测 1 4种脂肪酸的总量 ,青年正常组大于青年诱导组 (P <0 .0 1 ) ,青年正常组大于老年正常组 (P <0 .0 5 )。不饱和脂肪酸与脂肪酸总量的比例 ,老年诱导组大于老年正常组 (P <0 .0 5 ) ,青年正常组大于老年正常组 (P <0 .0 5 )。长链脂肪酸与脂肪酸总量的比例 ,老年正常组小于老年诱导组 (P <0 .0 5 )。结果表明 ,用DEHP诱导大鼠肝过氧化物酶体增值 ,影响肝线粒体脂肪酸正常代谢 ,使线粒体膜结构发生变化 ,这种变化 ,青年鼠与老年鼠不同     

The Features of Copper Metabolism in the Rat Liver during Development

Strong interest in copper homeostasis is due to the fact that copper is simultaneously a catalytic co-factor of the vital enzymes, a participant in signaling, and a toxic agent provoking oxidative stress. In mammals, during development copper metabolism is conformed to two types. In embryonic type copper metabolism (ETCM), newborns accumulate copper to high level in the liver because its excretion via bile is blocked; and serum copper concentration is low because ceruloplasmin (the main copper-containing protein of plasma) gene expression is repressed. In the late weaning, the ETCM switches to the adult type copper metabolism (ATCM), which is manifested by the unlocking of copper excretion and the induction of ceruloplasmin gene activity. The considerable progress has been made in the understanding of the molecular basis of copper metabolic turnover in the ATCM, but many aspects of the copper homeostasis in the ETCM remain unclear. The aim of this study was to investigate the copper metabolism during transition from the ETCM (up to 12-days-old) to the ATCM in the rats. It was shown that in the liver, copper was accumulated in the nuclei during the first 5 days of life, and then it was re-located to the mitochondria. In parallel with the mitochondria, copper bulk bound with cytosolic metallothionein was increased. All compartments of the liver cells rapidly lost most of their copper on the 13^th day of life. In newborns, serum copper concentration was low, and its major fraction was associated with holo-Cp, however, a small portion of copper was bound to extracellular metallothionein and a substance that was slowly eluted during gel-filtration. In adults, serum copper concentration increased by about a factor of 3, while metallothionein-bound copper level decreased by a factor of 2. During development, the expression level of Cp, Sod1, Cox4i1, Atp7b, Ctr1, Ctr2, Cox17, and Ccs genes was significantly increased, and metallothionein was decreased. Atp7a gene’s activity was fully repressed. The copper routes in newborns are discussed.     

Monoamine Oxidase Activity of Mitochondria Prepared from Rat Liver and Rat Heart

Abstract: The effect of agents that change the respiratory state of the mitochondrion on tyramine oxidation was investigated. Neither uncoupler nor ADP and P_t in the presence of substrate produced any change in the rate of tyramine oxidation, as judged by direct measurement of tyramine oxidation or by H₂O₂ production. We conclude that previously reported depression of monoamine oxidase activity by stimulated respiration was due to oxygen depletion.     

Mitochondria Isolated from Rat Brown Adipose Tissue and Liver

Mitochondrial fractions, relatively free from contamination by other cytoplasmic structures, have been isolated by differential centrifugation from homogenates of brown adipose tissue from starved rats. It was possible in such fractions to distinguish two types of mitochondria in this tissue. Type I mitochondria, when morphologically intact, are limited by a bilaminar membrane and show regular parallel cristae. In isolated fractions, a proportion of these mitochondria are swollen, vacuolation occurring within the cristae between their limiting membranes. Type II mitochondria are distinguished from the more numerous type I bodies by the opaque appearance of their matrix. They are limited by a membrane which is in part single, and in part double. They show a few, but crisply outlined internal membranes. Vacuolation of this type of mitochondrion has not been observed. Vacuolation comparable to that in brown fat mitochondria was also observed between the two laminae of the enclosing membrane and within the cristae of liver mitochondria.     

Isolation of Rat Liver Mitochondria and of Their Ribonucleic Acid

Mitochondria prepared from normal or regenerating rat liver appeared homogeneous on examination by electron microscopy. Ribonucleic acid (RNA) isolated from such mitochondria by phenol extraction or by deproteinization without phenol was resolved on sucrose density gradients into 18S, 12S and 4S optical density peaks. Administration of 5-[³H]-uridine to normal or partially hepatectomixed animals for 16 hours resulted in the labeling of A IS, 36S, 28–29S, 14S, 9–10S and 4S RNA species. Labeling of 18S RNA from regenerating liver but not from normal liver was also observed.     

Neonatal Hypothyroidism Affects the Adenine Nucleotides Metabolism in Astrocyte Cultures from Rat Brain

Neonatal hypothyroidism is associated with multiple and severe brain alterations. We recently demonstrated a significant increase in hydrolysis of AMP to adenosine in brain of hypothyroid rats at different ages. However, the origin of this effect was unclear. Considering the effects of adenine nucleotides to brain functions and the harmful effects of neonatal hypothyroidism to normal development of the central nervous system, in this study we investigated the metabolism of adenine nucleotides in hippocampal, cortical and cerebellar astrocyte cultures from rats submitted to neonatal hypothyroidism. ATP and AMP hydrolysis were enhanced by 52 and 210%, respectively, in cerebellar astrocytes from hypothyroid rats. In hippocampus of hypothyroid rats, the 47% increase in AMP hydrolysis was significantly reverted when the astrocytes were treated with T3. Therefore, the imbalance in the ATP and adenosine levels in astrocytes, during brain development, may contribute to some of the effects described in neonatal hypothyroidism.Elizandra Braganhol and Alessandra Nejar Bruno are first authors.     

Adenine Nucleotide Changes during Cold Acclimation of Winter Rape Plants

During the first stage of hardening of winter rape plants (Brassica napus L. var. oleifera L., cv. Górczański), marked increase of ATP content in leaves was observed. Lowering the temperature from 5 to 0 C (the second stage of hardening) had no further effect on ATP content. In roots, not capable of hardening, pronounced decrease of ATP content was noted after prolonged exposure to cold. It was found that increased ATP content and higher energy charge in cold-treated leaves were due to light and dark processes.     

Allopurinol Enhances Adenine Nucleotide Levels and Improves Myocardial Function in Isolated Hypoxic Rat Heart

Allopurinol, a competitive inhibitor of xanthine oxidase, was found to have a protective effect on ischemic myocardium. Its mechanism of action is still controversial. We used Langendorff isolated rat heart preparation to test the hypothesis that allopurinol could maintain a level of the adenine nucleotide pool (ATP, ADP, and AMP) that would protect and improve the functional activity of the heart during a period of hypoxia. Hearts were initially perfused for 30 min until steady state was attained. This was followed by 20 min of experimental perfusion divided into 5 min of control perfusion followed by 15 min of hypoxic perfusion with or without allopurinol in the perfusate. Hearts were quick-frozen and enzymatically analyzed for adenine nucleotides and creatine phosphate at the end of the hypoxic period. Left ventricular pressure, heart rate, and coronary flow were measured in all preparations. Allopurinol (0.1 mM) treated hearts had greater levels of ATP (12.3 ± 0.8 vs. 9.3 ± 0.8 µmol/g dry weight; p < 0.01). This improvement occurred in the presence as well as the absence of glucose. Total adenine nucleotides improved from 17 ± 1 to 20.3 ± 2.4 µmol/g dry weight (p < 0.01). This improvement also occurred in the presence as well as in the absence of glucose in the perfusate. It also improved cell energy state significantly in the presence as well as the absence of glucose. There was insignificant change in creatine phosphate. Allopurinol improved left ventricular pressure from 38 ± 7% to 55 ± 9% (p < 0.002) in the presence of glucose and from 8 ± 3% to 27 ± 6.3% (p < 0.001) in the absence of glucose. Coronary flow improved from 110 ± 5% to 120 ± 8% (p < 0.04) in the presence of glucose. These results support the suggestion that allopurinol at 0.1 mM exerts its protective effect on rat heart during hypoxia by enhancing the adenine nucleotide pool.     

Absence of Nitric-oxide Synthase in Sequentially Purified Rat Liver Mitochondria

Data, both for and against the presence of a mitochondrial nitric-oxide synthase (NOS) isoform, is in the refereed literature. However, irrefutable evidence has not been forthcoming. In light of this controversy, we designed studies to investigate the existence of the putative mitochondrial NOS. Using repeated differential centrifugation followed by Percoll gradient fractionation, ultrapure, never frozen rat liver mitochondria and submitochondrial particles were obtained. Following trypsin digestion and desalting, the mitochondrial samples were analyzed by nano-HPLC-coupled linear ion trap-mass spectrometry. Linear ion trap-mass spectrometry analyses of rat liver mitochondria as well as submitochondrial particles were negative for any peptide from any NOS isoform. However, recombinant neuronal NOS-derived peptides from spiked mitochondrial samples were easily detected, down to 50 fmol on column. The protein calmodulin (CaM), absolutely required for NOS activity, was absent, whereas peptides from CaM-spiked samples were detected. Also, l-[¹⁴C]arginine to l-[¹⁴C]citrulline conversion assays were negative for NOS activity. Finally, Western blot analyses of rat liver mitochondria, using NOS (neuronal or endothelial) and CaM antibodies, were negative for any NOS isoform or CaM. In conclusion, and in light of our present limits of detection, data from carefully conducted, properly controlled experiments for NOS detection, utilizing three independent yet complementary methodologies, independently as well as collectively, refute the claim that a NOS isoform exists within rat liver mitochondria.Nitric oxide (NO^·)² is a highly diffusible, hydrophobic, and gaseous free radical (1) that is responsible for autocrine and paracrine signaling activities (2). NO^· can readily partition into and through membranes (3–5) to influence biological functions such as blood pressure regulation, platelet aggregation and adhesion, neurotransmission, and cellular defense (4, 6–11). The mechanism by which NO^· influences biological functions is by binding to target proteins that contain heme and/or thiol(s). Alternatively, NO^· can combine with to produce the highly reactive species peroxynitrite.Mitochondria are highly compartmentalized, membranous organelles that contain abundant amounts of reactive hemoproteins and thiols (12, 13), to which NO^· may bind reversibly (14, 15) or irreversibly (16–18). Mitochondria also generate various amounts of during the process of cellular respiration (19, 20). Studies conducted during the past decade have suggested that NO^· can diffuse into mitochondria and cause mitochondrial dysfunction by reversibly inhibiting cytochrome c oxidase (14, 21, 22) and NADH dehydrogenase (23).In the mid-90s, a putative variant of NOS was proposed to reside within mitochondria. Initially, Kobzik et al. (24) and Hellsten and co-workers (25) observed an apparent endothelial NOS (eNOS) immunoreactivity in skeletal muscle mitochondria. Simultaneously, Bates et al. (26, 27) observed an apparent eNOS histochemical reactivity in inner mitochondrial membrane preparations, isolated from rat liver, brain, heart, skeletal muscle, and kidney. Tatoyan and Giulivi (28), acting on these initial observations, performed experiments in an attempt to confirm the identity of this putative mtNOS. Relying on immunochemical analysis, Tatoyan and Giulivi (28) claimed that inducible NOS (iNOS) was the NOS isoform present in rat liver mitochondria. This same group using mass spectrometry later presented data in support of the putative mtNOS being a variant of nNOS (29). Ghafourifar and Richter (30) had reported previously that the putative mtNOS was calcium-sensitive and constitutive in nature. Since these reports, different groups have reported the presence of each of the three main isoforms of NOS within mitochondria (29, 31, 32). Also, biochemical characterization of the putative mtNOS performed by Giulivi and co-workers (29) revealed certain post-translational modifications (myristoylation and phosphorylation of the protein) that are thought to be unique to eNOS. During the last decade, various reports have supported the presence of at least one of the three main isoforms of NOS residing in mitochondria. However, the more recent reports tend to question this claim (33–36). Because of the contradictory reports regarding the existence of a putative mtNOS, Brookes (33) compiled a critical and thorough review of the literature published up to 2003 dealing with the putative mtNOS. This review brought to light the diverse technical issues involved in the aforementioned studies. Major issues were the degree of purity of mitochondrial preparations (37, 38), shortcomings of measurement methodology (29, 39–41), use of inappropriate, or total lack of, experimental controls and confusing technical practices. Lacza et al. (42) has reviewed the more recent developments in the area of mitochondrial NO^· production and discussed some of the shortcomings of certain techniques still being used.In light of this ongoing controversy regarding the presence or absence of a mtNOS, we designed and carefully conducted properly controlled studies to either confirm or refute the existence of any NOS isoform within mitochondria. Ultrapure rat liver mitochondria were isolated using repeated differential centrifugation followed by Percoll gradient purification. Proteomic analyses were then performed using a nano-HPLC-coupled nanospray LTQ-MS. To avoid the interfering factors that are rampant in NO^· trapping assays (43), the NOS-catalyzed conversion of l-[¹⁴C]arginine to l-[¹⁴C]citrulline was used to probe for NOS activity in mitochondria. Appropriate controls were employed and, for inhibition studies, high concentrations of l-thiocitrulline (TC) (44) were used. Additionally, immunochemical analyses were performed with ultrapure mitochondria using nNOS, eNOS, and CaM antibodies. The problems faced with the commonly used techniques in mtNOS studies are discussed.     

山羊卵母细胞体外成熟过程中线粒体的动态分布

目的研究山羊卵母细胞减数分裂过程中线粒体的动态分布。方法收集山羊卵母细胞,在M199中分别培养4、8、12、16、20和24 h,用特异性线粒体标记探针进行标记,用激光扫描共聚焦显微镜观察线粒体的分布情况。结果生发泡期线粒体多分散在卵母细胞的胞质内,并且距生发泡有一定的距离;生发泡破裂期线粒体逐渐移向染色质;第一次减数分裂中期与第二次减数分裂中期线粒体成簇密布在染色体周围。排出的第一极体中也含有大量的线粒体。结论同其他哺乳动物卵母细胞体外成熟过程中线粒体分布情况相比,线粒体在山羊卵母细胞中的分布具有明显的相似性。线粒体密布在成熟卵母细胞染色体周围可能与极体的排出和受精后染色体的迁移有关。     

Atractyloside Inhibition of Adenine Nucleotide Translocation in Mitochondria from Hypocotyls of Vigna sinensis cv. Seridó

The translocation of adenine nucleotides into mitochondria isolated from hypocotyls of Vigna sinensis (L.) Savi cv. Serido was examined as a function of oxidative phosphorylation. Mitochondria membrane integrity was assessed by respiratory control and ADP:O ratios. A kinetic analysis of the translocation of adenosine diphosphate into the mitochondria revealed that the mechanism of translocation obeys classical Michaclis-Menten kinetics with a Km of 25 μM for adenosine diphosphate. At moderate ratios of atraetyloside to adenosine diphosphate (lower than 0.03), atractyloside appears to be a competitive inhibitor of the translocation process, with a Ki of 0.4 μM. However, non-linear kinetic parameters are observed with ratios higher than 0.06. A concentration of 2.5 μM atractyloside is sufficient to reduce the translocation of 100 μm ADP by 50%. This represents a higher level of sensitivity to atractyloside than reported for other plants.     

Kinetic Properties of Adenine Nucleotide Analogues Against Purified 5-Phosphoribosyl-1-pyrophosphate Synthetases from E. coli,Rat Liver and Human Erythrocytes

Abstract

The nucleoside analogue 2′,3′-dideoxyadenosine (ddA), the phosphonate isostere of 2′,3′-dideoxy-2′,3′-didehydro-adenosine (d4A) 5′-monophosphate (d4API), and the acyclic nucleoside phosphonates PMEoA, PMEA, FPMPA and PMPA are potent and selective antiretroviral agents. We found that these compounds are recognized as substrates by the PRPP synthetases from E. coli, rat liver and human erythrocytes, as their monophosphate and triphosphate form in the reverse and forward reaction, respectively. In particular, ddA-5′-monophosphate (ddAMP) and ddA-5′-triphosphate proved to be excellent substrates for the enzymes. D4API was a relatively good substrate of the rat liver and human erythrocyte PRPP synthetases. The acyclic nucleoside phosphonates were rather poor substrates, as evident from their low V_max values. None of the PRPP synthetases are found to act stereospecifically: they recognized both the S- and R-enantiomers of FPMPA and PMPA in a comparably efficient manner. Our data indicate that PRPP synthetase may recognize a much broader range of adenine nucleotide analogues than previously thought.     

Effect of Chlorophenol Analogues on the Oxidative Phosphorylation in Rat Liver Mitochondria

The inhibition of chlorophenol analogues on oxidative phosphorylation in rat liver mitochondria was studied using polarographic technique and some new findings that not only pentachlorophenol (PCP) but also other analogues inhibited the oxidative phoshorylation in a similar manner were made. The inhibitory activity was found to be roughly correlated with its dissociation constant of the inhibitor, PCP being the strongest, varying with the number and position of chlorine atoms in the molecule. The mode of the inhibition was classified into three types and discussed in detail.     

Changes of Adenine Nucleotide Levels in Chora Internodes during Metabolic Inhibition

The internal ATP concentration of Chara internodes was measuredduring metabolic poisoning. When the Chara was kept in the dark,the ATP level did not show any marked change at least for thefirst hour. Later it decreased slowly to less than half in about4 days. The decrease in the ATP level was accelerated when theChara was treated with 2 µM triphenyltin chloride (TPC),0.2 mM 2,4-dinitrophenol (DNP), 1 mM monoiodoacetic acid (MIA)or 50 µM DCCD. The final decreased level of ATP in TPCor DNP was about 50% in the light, but less than 40% in thedark. The speed of the decrease in the ATP level depended onthe concentration of these poisons. Additional application of1 mM MIA lowered the final level to almost 10%. Simultaneousmeasurements of ADP and AMP concentrations showed a temporaryincrease of ADP and a later slow increase of AMP during poisoning. (Received May 26, 1983; Accepted August 26, 1983)