Enrique Jaimovich

Endoplasmic reticulum and the unfolded protein response: dynamics and metabolic integration.

The endoplasmic reticulum (ER) is a dynamic intracellular organelle with multiple functions essential for cellular homeostasis, development, and stress responsiveness. In response to cellular stress, a well-established signaling cascade, the unfolded protein response (UPR), is activated. This intricate mechanism is an important means of re-establishing cellular homeostasis and alleviating the inciting stress. Now, emerging evidence has demonstrated that the UPR influences cellular metabolism through diverse mechanisms, including calcium and lipid transfer, raising the prospect of involvement of these processes in the pathogenesis of disease, including neurodegeneration, cancer, diabetes mellitus and cardiovascular disease. Here, we review the distinct functions of the ER and UPR from a metabolic point of view, highlighting their association with prevalent pathologies.

Myotube depolarization generates reactive oxygen species through NAD(P)H oxidase; ROS‐elicited Ca2+ stimulates ERK, CREB, early genes

Controlled generation of reactive oxygen species (ROS) may contribute to physiological intracellular signaling events. We determined ROS generation in primary cultures of rat skeletal muscle after field stimulation (400 1‐ms pulses at a frequency of 45 Hz) or after depolarization with 65 mM K+ for 1 min. Both protocols induced a long lasting increase in dichlorofluorescein fluorescence used as ROS indicator. Addition of diphenyleneiodonium (DPI), an inhibitor of NAD(P)H oxidase, PEG‐catalase, a ROS scavenger, or nifedipine, an inhibitor of the skeletal muscle voltage sensor, significantly reduced this increase. Myotubes contained both the p47phox and gp91phox phagocytic NAD(P)H oxidase subunits, as revealed by immunodetection. To study the effects of ROS, myotubes were exposed to hydrogen peroxide (H2O2) at concentrations (100–200 µM) that did not alter cell viability; H2O2 induced a transient intracellular Ca2+ rise, measured as fluo‐3 fluorescence. Minutes after Ca2+ signal initiation, an increase in ERK1/2 and CREB phosphorylation and of mRNA for the early genes c‐fos and c‐jun was detected. Inhibition of ryanodine receptor (RyR) decreased all effects induced by H2O2 and NAD(P)H oxidase inhibitors DPI and apocynin decreased ryanodine‐sensitive calcium signals. Activity‐dependent ROS generation is likely to be involved in regulation of calcium‐controlled intracellular signaling pathways in muscle cells. J. Cell. Physiol. 209: 379–388, 2006.

ATP Released by Electrical Stimuli Elicits Calcium Transients and Gene Expression in Skeletal Muscle

ATP released from cells is known to activate plasma membrane P2X (ionotropic) or P2Y (metabotropic) receptors. In skeletal muscle cells, depolarizing stimuli induce both a fast calcium signal associated with contraction and a slow signal that regulates gene expression. Here we show that nucleotides released to the extracellular medium by electrical stimulation are partly involved in the fast component and are largely responsible for the slow signals. In rat skeletal myotubes, a tetanic stimulus (45 Hz, 400 1-ms pulses) rapidly increased extracellular levels of ATP, ADP, and AMP after 15 s to 3 min. Exogenous ATP induced an increase in intracellular free Ca2+ concentration, with an EC50 value of 7.8 ± 3.1 μm. Exogenous ADP, UTP, and UDP also promoted calcium transients. Both fast and slow calcium signals evoked by tetanic stimulation were inhibited by either 100 μm suramin or 2 units/ml apyrase. Apyrase also reduced fast and slow calcium signals evoked by tetanus (45 Hz, 400 0.3-ms pulses) in isolated mouse adult skeletal fibers. A likely candidate for the ATP release pathway is the pannexin-1 hemichannel; its blockers inhibited both calcium transients and ATP release. The dihydropyridine receptor co-precipitated with both the P2Y2 receptor and pannexin-1. As reported previously for electrical stimulation, 500 μm ATP significantly increased mRNA expression for both c-fos and interleukin 6. Our results suggest that nucleotides released during skeletal muscle activity through pannexin-1 hemichannels act through P2X and P2Y receptors to modulate both Ca2+ homeostasis and muscle physiology.

Dihydropyridine Receptors as Voltage Sensors for a Depolarization-evoked, IP3R-mediated, Slow Calcium Signal in Skeletal Muscle Cells

The dihydropyridine receptor (DHPR), normally a voltage-dependent calcium channel, functions in skeletal muscle essentially as a voltage sensor, triggering intracellular calcium release for excitation-contraction coupling. In addition to this fast calcium release, via ryanodine receptor (RYR) channels, depolarization of skeletal myotubes evokes slow calcium waves, unrelated to contraction, that involve the cell nucleus (Jaimovich, E., R. Reyes, J.L. Liberona, and J.A. Powell. 2000. Am. J. Physiol. Cell Physiol. 278:C998–C1010). We tested the hypothesis that DHPR may also be the voltage sensor for these slow calcium signals. In cultures of primary rat myotubes, 10 μM nifedipine (a DHPR inhibitor) completely blocked the slow calcium (fluo-3-fluorescence) transient after 47 mM K+ depolarization and only partially reduced the fast Ca2+ signal. Dysgenic myotubes from the GLT cell line, which do not express the α1 subunit of the DHPR, did not show either type of calcium transient following depolarization. After transfection of the α1 DNA into the GLT cells, K+ depolarization induced slow calcium transients that were similar to those present in normal C2C12 and normal NLT cell lines. Slow calcium transients in transfected cells were blocked by nifedipine as well as by the G protein inhibitor, pertussis toxin, but not by ryanodine, the RYR inhibitor. Since slow Ca2+ transients appear to be mediated by IP3, we measured the increase of IP3 mass after K+ depolarization. The IP3 transient seen in control cells was inhibited by nifedipine and was absent in nontransfected dysgenic cells, but α1-transfected cells recovered the depolarization-induced IP3 transient. In normal myotubes, 10 μM nifedipine, but not ryanodine, inhibited c-jun and c-fos mRNA increase after K+ depolarization. These results suggest a role for DHPR-mediated calcium signals in regulation of early gene expression. A model of excitation-transcription coupling is presented in which both G proteins and IP3 appear as important downstream mediators after sensing of depolarization by DHPR.

NADPH Oxidase and Hydrogen Peroxide Mediate Insulin-induced Calcium Increase in Skeletal Muscle Cells

Skeletal muscle is one of the main physiological targets of insulin, a hormone that triggers a complex signaling cascade and that enhances the production of reactive oxygen species (ROS) in different cell types. ROS, currently considered second messengers, produce redox modifications in proteins such as ion channels that induce changes in their functional properties. In myotubes, insulin also enhances calcium release from intracellular stores. In this work, we studied in myotubes whether insulin stimulated ROS production and investigated the mechanisms underlying the insulin-dependent calcium increase: in particular, whether the late phase of the Ca2+ increase induced by insulin required ROS. We found that insulin stimulated ROS production, as detected with the probe 2′,7′-dichlorofluorescein diacetate (CM-H2DCFDA). We used the translocation of p47phox from the cytoplasm to the plasma membrane as a marker of the activation of NADPH oxidase. Insulin-stimulated ROS generation was suppressed by the NADPH oxidase inhibitor apocynin and by small interfering RNA against p47phox, a regulatory NADPH oxidase subunit. Additionally, both protein kinase C and phosphatidylinositol 3-kinase are presumably involved in insulin-induced ROS generation because bisindolylmaleimide, a nonspecific protein kinase C inhibitor, and LY290042, an inhibitor of phosphatidylinositol 3-kinase, inhibited this increase. Bisindolylmaleimide, LY290042, apocynin, small interfering RNA against p47phox, and two drugs that interfere with inositol 1,4,5-trisphosphate-mediated Ca2+ release, xestospongin C and U73122, inhibited the intracellular Ca2+ increase produced by insulin. These combined results strongly suggest that insulin induces ROS generation trough NADPH activation and that this ROS increase is required for the intracellular Ca2+ rise mediated by inositol 1,4,5-trisphosphate receptors.

Insulin-like Growth Factor-1 Induces an Inositol 1,4,5-Trisphosphate-dependent Increase in Nuclear and Cytosolic Calcium in Cultured Rat Cardiac Myocytes*

In the heart, insulin-like growth factor-1 (IGF-1) is a pro-hypertrophic and anti-apoptotic peptide. In cultured rat cardiomyocytes, IGF-1 induced a fast and transient increase in Ca2+i levels apparent both in the nucleus and cytosol, releasing this ion from intracellular stores through an inositol 1,4,5-trisphosphate (IP3)-dependent signaling pathway. Intracellular IP3 levels increased after IGF-1 stimulation in both the presence and absence of extracellular Ca2+. A different spatial distribution of IP3 receptor isoforms in cardiomyocytes was found. Ryanodine did not prevent the IGF-1-induced increase of Ca2+i levels but inhibited the basal and spontaneous Ca2+i oscillations observed when cardiac myocytes were incubated in Ca2+-containing resting media. Spatial analysis of fluorescence images of IGF-1-stimulated cardiomyocytes incubated in Ca2+-containing resting media showed an early increase in Ca2+i, initially localized in the nucleus. Calcium imaging suggested that part of the Ca2+ released by stimulation with IGF-1 was initially contained in the perinuclear region. The IGF-1-induced increase on Ca2+i levels was prevented by 1,2-bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid-AM, thapsigargin, xestospongin C, 2-aminoethoxy diphenyl borate, U-73122, pertussis toxin, and βARKct (a peptide inhibitor of Gβγ signaling). Pertussis toxin also prevented the IGF-1-dependent IP3 mass increase. Genistein treatment largely decreased the IGF-1-induced changes in both Ca2+i and IP3. LY29402 (but not PD98059) also prevented the IGF-1-dependent Ca2+i increase. Both pertussis toxin and U73122 prevented the IGF-1-dependent induction of both ERKs and protein kinase B. We conclude that IGF-1 increases Ca2+i levels in cultured cardiac myocytes through a Gβγ subunit of a pertussis toxin-sensitive G protein-PI3K-phospholipase C signaling pathway that involves participation of IP3.

Harmaline: A competitive inhibitor of Na Ion in the (Na++K+)-ATPase system

SummaryExperimental evidence is given that the hallucinogen harmaline (HME) behaves as an inhibitor of the (Na++K+)-ATPase system, specifically in the Na+-dependent phosphorylation reaction. HME at 0.3 to 3mm inhibited several membrane ATPase preparations such as those from human erythrocytes, rat brain and squid retinal axons. The same concentration blocked Na+ outflow from squid giant axons. The behavior of several harmane derivatives such as harmine, harmalol and harmaline demonstrated that certain groups influenced the concentration for 50% inhibition of the ATPase system. The following evidence demonstrated that HME blocked the formation of the phosphorylated intermediate by competition with Na ions in the (Na++K+)-ATPase reaction in rat brain. (1) The HME effect on the overall (Na++K+)-ATPase reaction showed a fully competitive inhibition with respect to Na ion concentration. (2) The inhibition of the Na+-stimulated phosphorylation by HME was fully competitive with respect to Na ions, with or without oligomycin present. (3) HME inhibited the effect of ADP on the phosphorylation reaction using32P-ATP. (4) HME did not accelerate the rate of membrane dephosphorylation by means of32P-ATP and cold ATP.From the behavior of HME as a competitive inhibitor at Na ion sites of the (Na++K+)-ATPase reactions one may gain information about (a) The chemical nature of Na+ sites which may be responsible for the selectivity of this cation, and (b) The sequence of Na+ and ATP entrance into the Na+-dependent phosphorylation reaction. The experimental evidence supports the hypothesis that the entrance of Na+ into the enzyme system may precede the formation of the phosphorylated intermediate.

Nuclear inositol 1,4,5-trisphosphate receptors regulate local Ca2+ transients and modulate cAMP response element binding protein phosphorylation.

Several lines of evidence indicate that increases in nuclear Ca2+ have specific biological effects that differ from those of cytosolic Ca2+, suggesting that they occur independently. The mechanisms involved in controlling nuclear Ca2+ signaling are both controversial and still poorly understood. Using hypotonic shock combined with mechanical disruption, we obtained and characterized a fraction of purified nuclei from cultured rat skeletal myotubes. Both immunoblot studies and radiolabeled inositol 1,4,5-trisphosphate [IP3] binding revealed an important concentration of IP3 receptors in the nuclear fraction. Immunofluorescence and immunoelectron microscopy studies localized type-1 and type-3 IP3 receptors in the nucleus with type-1 receptors preferentially localized in the inner nuclear membrane. Type-2 IP3 receptor was confined to the sarcoplasmic reticulum. Isolated nuclei responded to IP3 with rapid and transient Ca2+ concentration elevations, which were inhibited by known blockers of IP3 signals. Similar results were obtained with isolated nuclei from the 1B5 cell line, which does not express ryanodine receptors but releases nuclear Ca2+ in an IP3-dependent manner. Nuclear Ca2+ increases triggered by IP3 evoked phosphorylation of cAMP response element binding protein with kinetics compatible with sequential activation. These results support the idea that Ca2+ signals, mediated by nuclear IP3 receptors in muscle cells, are part of a distinct Ca2+ release component that originates in the nucleus and probably participates in gene regulation mediated by cAMP response element binding protein.

Local Control of Nuclear Calcium Signaling in Cardiac Myocytes by Perinuclear Microdomains of Sarcolemmal Insulin-Like Growth Factor 1 Receptors

Rationale: The ability of a cell to independently regulate nuclear and cytosolic Ca2+ signaling is currently attributed to the differential distribution of inositol 1,4,5-trisphosphate receptor channel isoforms in the nucleoplasmic versus the endoplasmic reticulum. In cardiac myocytes, T-tubules confer the necessary compartmentation of Ca2+ signals, which allows sarcomere contraction in response to plasma membrane depolarization, but whether there is a similar structure tunneling extracellular stimulation to control nuclear Ca2+ signals locally has not been explored. Objective: To study the role of perinuclear sarcolemma in selective nuclear Ca2+ signaling. Methods and Results: We report here that insulin-like growth factor 1 triggers a fast and independent nuclear Ca2+ signal in neonatal rat cardiac myocytes, human embryonic cardiac myocytes, and adult rat cardiac myocytes. This fast and localized response is achieved by activation of insulin-like growth factor 1 receptor signaling complexes present in perinuclear invaginations of the plasma membrane. The perinuclear insulin-like growth factor 1 receptor pool connects extracellular stimulation to local activation of nuclear Ca2+ signaling and transcriptional upregulation through the perinuclear hydrolysis of phosphatidylinositol 4,5-biphosphate inositol 1,4,5-trisphosphate production, nuclear Ca2+ release, and activation of the transcription factor myocyte-enhancing factor 2C. Genetically engineered Ca2+ buffers—parvalbumin—with cytosolic or nuclear localization demonstrated that the nuclear Ca2+ handling system is physically and functionally segregated from the cytosolic Ca2+ signaling machinery. Conclusions: These data reveal the existence of an inositol 1,4,5-trisphosphate–dependent nuclear Ca2+ toolkit located in direct apposition to the cell surface, which allows the local control of rapid and independent activation of nuclear Ca2+ signaling in response to an extracellular ligand.

Differences in both inositol 1,4,5-trisphosphate mass and inositol 1,4,5-trisphosphate receptors between normal and dystrophic skeletal muscle cell lines

Human normal (RCMH) and Duchenne muscular dystrophy (RCDMD) cell lines, as well as newly developed normal and dystrophic murine cell lines, were used for the study of both changes in inositol 1,4,5‐trisphosphate (IP3) mass and IP3 binding to receptors. Basal levels of IP3 were increased two‐ to threefold in dystrophic human and murine cell lines compared to normal cell lines. Potassium depolarization induced a time‐dependent IP3 rise in normal human cells and cells of the myogenic mouse cell line (129CB3), which returned to their basal levels after 60 s. However, in the human dystrophic cell line (RCDMD), IP3 levels remained high up to 200 s after potassium depolarization. Expression of IP3 receptors was studied measuring specific binding of 3H‐IP3 in the murine cell lines (normal 129CB3 and dystrophic mdx XLT 4‐2). All the cell lines bind 3H‐IP3 with relatively high affinity (Kd: between 40 and 100 nmol/L). IP3 receptors are concentrated in the nuclear fraction, and their density is significantly higher in dystrophic cells compared to normal. These findings together with high basal levels of IP3 mass suggest a possible role for this system in the deficiency of intracellular calcium regulation in Duchenne muscular dystrophy.