Isoform- and tissue-specific regulation of the Ca(2+)-sensitive transcription factor NFAT in cardiac myocytes and heart failure.

Nuclear factors of activated T cells (NFATs) are Ca(2+)-sensitive transcription factors that have been implicated in hypertrophy, heart failure (HF), and arrhythmias. Cytosolic NFAT is activated by dephosphorylation by the Ca(2+)-sensitive phosphatase calcineurin, resulting in translocation to the nucleus, which is opposed by kinase activity, rephosphorylation, and nuclear export. Four different NFAT isoforms are expressed in the heart. The activation and regulation of NFAT in adult cardiac myocytes, which may depend on the NFAT isoform and cell type, are not fully understood. This study compared basal localization, import, and export of NFATc1 and NFATc3 in adult atrial and ventricular myocytes to identify isoform- and tissue-specific regulatory mechanisms of NFAT activation under physiological conditions and in HF. NFAT-green fluorescent protein fusion proteins and NFAT immunocytochemistry were used to analyze NFAT regulation in adult cat and rabbit myocytes. NFATc1 displayed basal nuclear localization in atrial and ventricular myocytes, an effect that was attenuated by reducing intracellular Ca(2+) concentration and inhibiting calcineurin, and enhanced by the inhibition of nuclear export. In contrast, NFATc3 was localized to the cytoplasm but could be driven to the nucleus by angiotensin II and endothelin-1 stimulation in atrial, but not ventricular, cells. Inhibition of nuclear export (by leptomycin B) facilitated nuclear localization in both cell types. Ventricular myocytes from HF rabbits showed increased basal nuclear localization of endogenous NFATc3 and reduced responsiveness of NFAT translocation to phenylephrine stimulation. In control myocytes, Ca(2+) overload, leading to spontaneous Ca(2+) waves, induced substantial translocation of NFATc3 to the nucleus. We conclude that the activation of NFAT in adult cardiomyocytes is isoform and tissue specific and is tightly controlled by nuclear export. NFAT is activated in myocytes from HF animals and may be secondary to Ca(2+) overload.

Inositol-1,4,5-trisphosphate-mediated spontaneous activity in mouse embryonic stem cell-derived cardiomyocytes.

Embryonic stem cell-derived cardiomyocytes (ESdCs) have been proposed as a source for cardiac cell-replacement therapy. The aim of this study was to determine the Ca2+-handling mechanisms that determine the frequency and duration of spontaneous Ca2+ transients in single ESdCs. With laser scanning confocal microscopy using the Ca2+-sensitive dye Fluo-4/AM, we determined that spontaneous Ca2+ transients in ESdCs at the onset of beating (day 9) depend on Ca2+ entry across the plasma membrane (50%) whereas Ca2+-induced Ca2+ release is the major contributor to Ca2+ transients in ESdCs after 16 days (72%). Likewise, Ca2+ extrusion in 9-day-old ESdCs depends on Na+-Ca2+ exchange (50.0+/-8%) whereas Ca2+ reuptake by the sarco(endo)plasmic Ca2+ ATPase (72+/-5%) dominates in further differentiated cells. Spontaneous Ca2+ transients were suppressed by the inositol-1,4,5-trisphosphate (IP3) receptor (IP3R) blocker 2-aminoethoxydiphenyl borate (2-APB) and the phospholipase C blocker U73122 but continued in the presence of caffeine. Stimulation of IP3 production by phenylephrine or endothelin-1 had a positive chronotropic effect that could be reversed by U73122 and 2-APB. The presence of Ca2+-free solution and block of L-type Ca2+ channels by nifedipine also resulted in a cessation of spontaneous activity. Overall, IP3R-mediated Ca2+ release in ESdCs is translated into a depolarization of the plasma membrane and a whole-cell Ca2+ transient is subsequently induced by voltage-dependent Ca2+ influx. Although ryanodine receptor-mediated Ca2+ release amplifies the IP3R-induced trigger for the Ca2+ transients and modulates its frequencies, it is not a prerequisite for spontaneous activity. The results of this study offer important insight into the role of IP3R-mediated Ca2+ release for pacemaker activity in differentiating cardiomyocytes.

Cell cycle-dependent calcium oscillations in mouse embryonic stem cells.

During cell cycle progression, somatic cells exhibit different patterns of intracellular Ca(2+) signals during the G(0) phase, the transition from G(1) to S, and from G(2) to M. Because pluripotent embryonic stem (ES) cells progress through cell cycle without the gap phases G(1) and G(2), we aimed to determine whether mouse ES (mES) cells still exhibit characteristic changes of intracellular Ca(2+) concentration during cell cycle progression. With confocal imaging of the Ca(2+)-sensitive dye fluo-4 AM, we identified that undifferentiated mES cells exhibit spontaneous Ca(2+) oscillations. In control cultures where 50.4% of the cells reside in the S phase of the cell cycle, oscillations appeared in 36% of the cells within a colony. Oscillations were not initiated by Ca(2+) influx but depended on inositol 1,4,5-trisphosphate (IP(3))-mediated Ca(2+) release and the refilling of intracellular stores by a store-operated Ca(2+) influx (SOC) mechanism. Using cell cycle synchronization, we determined that Ca(2+) oscillations were confined to the G(1)/S phase ( approximately 70% oscillating cells vs. G(2)/M with approximately 15% oscillating cells) of the cell cycle. ATP induced Ca(2+) oscillations, and activation of SOC could be induced in G(1)/S and G(2)/M synchronized cells. Intracellular Ca(2+) stores were not depleted, and all three IP(3) receptor isoforms were present throughout the cell cycle. Cell cycle analysis after EGTA, BAPTA-AM, 2-aminoethoxydiphenyl borate, thapsigargin, or U-73122 treatment emphasized that IP(3)-mediated Ca(2+) release is necessary for cell cycle progression through G(1)/S. Because the IP(3) receptor sensitizer thimerosal induced Ca(2+) oscillations only in G(1)/S, we propose that changes in IP(3) receptor sensitivity or basal levels of IP(3) could be the basis for the G(1)/S-confined Ca(2+) oscillations.

Molecular regulation of cholesterol biosynthesis: implications in carcinogenesis.

Cholesterol synthesis was demonstrated to be mandatory for cellular growth and serves to supply one of the necessary building blocks for new membranes demanded by dividing cells during growth. The mevalonate pathway, which is regulated through a finely tuned mechanism, is responsible mainly for cholesterol enrichment to cells. Among the various steps, the production of mevalonate from 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) is the most critically regulated step catalyzed by HMG-CoA reductase. The ability of sterols to regulate both the transcriptional rates of the reductase gene and the degradative machinery for the reductase protein provides a multilevel system for controlling the expression of this enzyme. Much convincing evidence indicates that cells manifest a higher flux through the mevalonate pathway when proliferating than when they are in the cell cycle arrest condition; furthermore, tumors undergo deregulated cholesterogenesis mainly at the critical rate-controlling juncture (i.e., the reaction catalyzed by HMG-CoA reductase). The mevalonate component of the cholesterol biosynthesis plays a key role in controlling cell proliferation by generating prenyl intermediates, particularly farnesyl and geranyl-geranyl moieties. These isoprenoids covalently modify and thus modulate the biological activity of signal transducing proteins, such as that of the Ras superfamily. The prenylated Ras-mediated signal transduction pathway provides much of the molecular information needed to trigger cell proliferation. Therefore, depletion of mevalonate can block both the processing and the transforming activities of Ras, indicating that drugs such as lovastatin and compactin, which had previously been exploited for lowering cholesterol levels, may be useful chemotherapeutic agents for treating tumors harboring oncogenic Ras mutation. In addition, Ras prenylation, which provides much of the molecular information needed to trigger cell proliferation, represents an inviting target for the design of chemotherapeutic drugs that would interrupt such signaling events and arrest tumor cell proliferation.