Project description:The maturation of glucagon-stimulated Ruthenium Red-insensitive Ca2+-transport activity was determined in livers of rats ranging in age from 5 days preterm to 10 weeks of adult life. Previous indications are that this activity is confined to vesicles derived mainly from the endoplasmic reticulum. Perinatal-rat liver contains near-adult values of Ruthenium Red-insensitive Ca2+-transport activity, and exhibits large transient increases in the rate of this activity at two stages of development, immediately after birth, and at 2-5 days after birth. The administration of glucagon to foetal rats, at developmental stages after 19.5 days of gestation (2.5 days before birth), results in a large stable increase (greater than 100%) of Ca2+-transport activity in a subsequently isolated 'heavy' microsomal fraction. That this fraction was enriched in vesicles derived from the rough endoplasmic reticulum was indicated by both an electron-microscopic examination and a marker-enzyme analysis of the subcellular fractions. The administration of glucagon into newborn animals only hours old does not enhance further the initial rate of Ca2+-transport activity, and from day 1 to 10 weeks after birth the administration of the hormone results in the moderate enhancement of Ca2+ transport. Experiments with cyclic AMP and inhibitors of phosphodiesterase activity suggest that cyclic AMP plays a key role in the enhancement by glucagon of Ruthenium Red-insensitive Ca2+ transport, and arguments are presented that this transport system has an important metabolic role in the redistribution of intracellular Ca2+ in liver tissue.

Project description:The maturation of Ca(2+) transport in mitochondria isolated from rat liver was examined, from 5 days before birth. The mitochondria used were isolated from liver homogenates by centrifugation at 22000g-min. Ca(2+) transport by mitochondria isolated from foetal liver is energy-dependent and Ruthenium Red-sensitive. The transmembrane pH gradient in these mitochondria is higher by about 7mV and the membrane potential lower by about 20mV than in adult mitochondria. The inclusion of 2mm-P(i) in the incubation medium enhances the protonmotive force by approx. 30mV. The rate of Ca(2+) influx in foetal mitochondria measured in buffered KCl plus succinate is low until about 2-3h after birth, when it increases to about 60% of adult values; approx. 24h later it has reached near-adult values. Higher rates of Ca(2+) influx are observed in the presence of 2mm-P(i); 3-5 days before birth the rates are about one-third of adult values and decline slightly as birth approaches. By 2-3h post partum they have reached adult values. The inclusion of 12.5mum-MgATP with the P(i) stimulates further the initial rate of Ca(2+) influx in foetal mitochondria. The rates observed are constant over the prenatal period examined and are 50-60% of those observed in adult mitochondria. Mitochondria isolated from foetal livers 4-5 days before birth retain the accumulated Ca(2+) for about 50min in the presence of 2mm-P(i). In the period 2 days before birth to birth, this ability is largely lost, but by 2-3h after birth Ca(2+) retention is similar to that of adult mitochondria. The presence of 12.5mum-MgATP progressively enhances the Ca(2+) retention time as development proceeds until 2-3h after birth, when it becomes less sensitive to added MgATP. Glucagon administration to older foetuses in utero enhances both the rate of mitochondrial Ca(2+) influx assayed in the presence of 2mm-P(i) and the time for which mitochondria retain accumulated Ca(2+) in the presence of 12.5mum-MgATP and 2mm-P(i). Its administration to neonatal animals leads to an increase in mitochondrial Ca(2+) retention similar to that seen in adult mitochondria. The data provide evidence that the Ruthenium Red-sensitive Ca(2+) transporter is potentially as active in foetal mitochondria 5 days before birth as it is in adult mitochondria. They also show that foetal mitochondria have an ability to retain accumulated Ca(2+) reminiscent of mitochondria from tumour cells and from hormone-challenged rat liver.

Project description:1. Ruthenium Red-insensitive Ca2+ transport in the mouse ascites sarcoma 180/TG is enriched in a 'heavy' microsomal fraction (microsomes) sedimented at 35 000 g for 20 min. The subcellular distribution of this Ca2+ transport differed from that of Ruthenium Red-sensitive Ca2+ transport and (Na+ + K+)-dependent ATPase activity, but was similar to that of glucose 6-phosphatase. 2. The affinity of this transport system for 'free' Ca2+ is high (Km approx. 6 microM) and that for MgATP somewhat lower (Km approx. 100 microM). Ca2+ transport by the tumour microsomes, by contrast with that by liver microsomes, was greatly stimulated by low concentrations of P1. 3. Although incubation of intact ascites cells with glucagon led to an increase in intracellular cyclic AMP, no stable increase in the initial rate of Ca2+ transport in the subsequently isolated 'heavy' microsomes could be detected as in similar experiments carried out previously with rat liver cells. Reconstitution experiments suggest that a deficiency exists in the tumour microsomal membrane such that an action of glucagon that is normally present in rat liver microsomes is not evoked.

Project description:1. Seven fractions sedimenting at between 3000 and 120000g-min were prepared from a rat liver homogenate by differential centrifugation in buffered iso-osmotic sucrose. The following measurements were carried out on each of these fractions: Ruthenium Red-sensitive Ca(2+) transport in the absence and in the presence of P(i) as well as in the presence of N-ethylmaleimide to prevent P(i) cycling, succinate-supported respiration in the absence and in the presence of ADP, the DeltaE and -59 DeltapH components of the protonmotive force, cytochrome oxidase, uncoupler-stimulated adenosine triphosphatase, alpha-glycerophosphate dehydrogenase, P(i) content and the effect on the ;resting' rate of respiration of repeated additions of a fixed Ca(2+) concentration. 2. Ca(2+) transport either in the presence or in the absence of added P(i) and in the presence of N-ethylmaleimide exhibits significantly higher rates in the fraction sedimenting at 8000g-min. By contrast, respiration in the presence or in the absence of added ADP and the values for DeltaE and -59 DeltapH were similar in those fractions sedimenting between 4000 and 20000g-min, indicating that the driving force for Ca(2+) transport was similar in each of these fractions. 3. Experiments designed to determine the capacity of the individual fractions for Ca(2+), as measured by the effect of repeated additions of Ca(2+) on the resting rate of respiration, showed that fraction 2, i.e. that sedimenting at 8000g-min, also exhibited the greatest tolerance towards the uncoupling action of the ion. 4. Of the three enzyme activity profiles, only that of alpha-glycerophosphate dehydrogenase was similar to that of Ca(2+) transport. Because previous workers have assigned this enzyme to loci in the inner peripheral membrane [Werner & Neupert (1972) Eur. J. Biochem.25, 379-396], it is concluded that the Ruthenium Red-sensitive Ca(2+)- transport system also is located in this domain of the inner membrane. The relation of these findings to the mechanisms of mitochondrial Ca(2+) transport and the biogenesis of mitochondria is discussed.

Project description:Vitrification reduces the fertilisation capacity and developmental ability of mammalian oocytes; this effect is closely associated with an abnormal increase of cytoplasmic free calcium ions ([Ca2+]i). However, little information about the mechanism by which vitrification increases [Ca2+]i levels or a procedure to regulate [Ca2+]i levels in these oocytes is available. Vitrified bovine oocytes were used to analyse the effect of vitrification on [Ca2+]i, endoplasmic reticulum Ca2+ (ER Ca2+), and mitochondrial Ca2+ (mCa2+) levels. Our results showed that vitrification, especially with dimethyl sulfoxide (DMSO), can induce ER Ca2+ release into the cytoplasm, consequently increasing the [Ca2+]i and mCa2+ levels. Supplementing the cells with 10 μM 1,2-bis (o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA-AM or BAPTA) significantly decreased the [Ca2+]i level and maintained the normal distribution of cortical granules in the vitrified bovine oocytes, increasing their fertilisation ability and cleavage rate after in vitro fertilisation (IVF). Treating vitrified bovine oocytes with 1 μM ruthenium red (RR) significantly inhibited the Ca2+ flux from the cytoplasm into mitochondria; maintained normal mCa2+ levels, mitochondrial membrane potential, and ATP content; and inhibited apoptosis. Treating vitrified oocytes with a combination of BAPTA and RR significantly improved embryo development and quality after IVF.

Project description:An EGTA (ethanedioxybis(ethylamine)tetra-acetic acid)-quench technique was developed for measuring initial rates of (45)Ca(2+) transport by rat liver mitochondria. This method was used in conjunction with studies of Ca(2+)-stimulated respiration to examine the mechanisms of inhibition of Ca(2+) transport by the lanthanides and Ruthenium Red. Ruthenium Red inhibits Ca(2+) transport non-competitively with K(i) 3x10(-8)m; there are 0.08nmol of carrier-specific binding sites/mg of protein. The inhibition by La(3+) is competitive (K(i)=2x10(-8)m); the concentration of lanthanide-sensitive sites is less than 0.001nmol/mg of protein. A further difference between their modes of action is that lanthanide inhibition diminishes with time whereas that by Ruthenium Red does not. Binding studies showed that both classes of inhibitor bind to a relatively large number of external sites (probably identical with the ;low-affinity' Ca(2+)-binding sites). La(3+) competes with Ruthenium Red for most of these sites, but a small fraction of the bound Ruthenium Red (less than 2nmol/mg of protein) is not displaced by La(3+). The results are discussed briefly in relation to possible models for a Ca(2+) carrier.

Project description:G protein-coupled receptors in intracellular organelles can be activated in response to membrane permeant ligands, which contributes to the diversity and specificity of agonist action. The opioid receptors (ORs) provide a striking example, where small molecule opioid drugs activate ORs in the Golgi apparatus within seconds of drug addition. To date, our knowledge on the signaling of intracellular GPCRs remains incomplete and it is unknown if the downstream events triggered by ORs in plasma membrane and Golgi apparatus differ. To address this gap, we analyzed OR-mediated gene expression changes upon treatment with impermeant peptide ligand DPDPE, permeant ligand SNC80 or ICI-SNC80 (Golgi-restricted signaling). We show that DOR activation in the Golgi does not trigger any gene transcription at these two time points as compare to plasma membrane receptors. The study delineates OR signal transduction with unprecedented resolution and reveals that the subcellular location defines the signaling effect promoted by opioid drugs.

Project description:For over 20 years, genetically encoded Ca2+ indicators have illuminated dynamic Ca2+ signaling activity in living cells and, more recently, whole organisms. We are just now beginning to understand how they work. Various fluorescence colors of these indicators have been developed, including red. Red ones are promising because longer wavelengths of light scatter less in tissue, making it possible to image deeper. They are engineered from a red fluorescent protein that is circularly permuted and fused to a Ca2+-sensing domain. When Ca2+ binds, a conformational change in the sensing domain causes a change in fluorescence. Three factors can contribute to this fluorescence change: 1) a shift in the protonation equilibrium of the chromophore, 2) a change in fluorescence quantum yield, and 3) a change in the extinction coefficient or the two-photon cross section, depending on if it is excited with one or two photons. Here, we conduct a systematic study of the photophysical properties of a range of red Ca2+ indicators to determine which factors are the most important. In total, we analyzed nine indicators, including jRGECO1a, K-GECO1, jRCaMP1a, R-GECO1, R-GECO1.2, CAR-GECO1, O-GECO1, REX-GECO1, and a new variant termed jREX-GECO1. We find that these could be separated into three classes that each rely on a particular set of factors. Furthermore, in some cases, the magnitude of the change in fluorescence was larger with two-photon excitation compared to one-photon because of a change in the two-photon cross section, by up to a factor of two.

Project description:As part of an ongoing effort to develop genetically encoded calcium ion (Ca2+) indicators we recently described a new variant, designated CH-GECO2.1, that is a genetic chimera of the red fluorescent protein (FP) mCherry, calmodulin (CaM), and a peptide that binds to Ca2+-bound CaM. In contrast to the closely related Ca2+ indicator R-GECO1, CH-GECO2.1 is characterized by a much higher affinity for Ca2+ and a sensing mechanism that does not involve direct modulation of the chromophore pKa. To probe the structural basis underlying the differences between CH-GECO2.1 and R-GECO1, and to gain a better understanding of the mechanism of CH-GECO2.1, we have constructed, purified, and characterized a large number of variants with strategic amino acid substitutions. This effort led us to identify Gln163 as the key residue involved in the conformational change that transduces the Ca2+ binding event into a change in the chromophore environment. In addition, we demonstrate that many of the substitutions that differentiate CH-GECO2.1 and R-GECO1 have little influence on both the Kd for Ca2+ and the sensing mechanism, and that the interdomain linkers and interfaces play important roles.

Project description:1. When rat spleen mitochondria are incubated with oxidizable substrates, added MgCl2 (greater than 150 muM free concentration) markedly stimulates state-4 respiration and lowers both the respiratory control and ADP/O ratios; this effect is reversible on addition of excess of EDTA. 2. With [gamma-32P]ATP as substrate, an Mg2+-stimulated ATPase (adenosine triphosphate) was identified in the atractyloside-insensitive and EDTA-accessible space of intact rat spleen mitochondria. 3. Oligomycin has no effect on the activity of the Mg2+-stimulated ATPase at a concentration (2.0mug/mg of protein) that completely inhibits the atractyloside-sensitive reaction. Of the two ATPase activities, only the atracytoloside sensitive reaction is stimulated (approx. 40%) by dinitrophenol. 4. On digitonin fractionation the atractyloside-insensitive Mg2+-stimulated ATPase co-purifies with the outer membrane-fraction of rat spleen mitochondria, whereas (as expected) the atractylosidesensitive activity co-purifies with the inner-membrane plus matrix fraction. 5. Stoicheiometric amounts of ADP and Pi are produced as the end products of ATP hydrolysis by purified outer-membrane fragments; no significant AMP production is detected during the time-course of the reaction. 6. The outer-membrane ATPase is present in rat kidney cortex and heart mitochondria as well as in spleen, but is absent from rat liver, thymus, brain, lung, diaphragm and skeletal muscle.