Receptors and ionic transporters in nuclear membranes: new targets for therapeutical pharmacological interventions

Work from our group and other laboratories showed that the nucleus could be considered as a cell within a cell. This is based on growing evidence of the presence and role of nuclear membrane G-protein coupled receptors and ionic transporters in the nuclear membranes of many cell types, including vascular endothelial cells, endocardial endothelial cells, vascular smooth muscle cells, cardiomyocytes, and hepatocytes. The nuclear membrane receptors were found to modulate the functioning of ionic transporters at the nuclear level, and thus contribute to regulation of nuclear ionic homeostasis. Nuclear membranes of the mentioned types of cells possess the same ionic transporters; however, the type of receptors is cell-type dependent. Regulation of cytosolic and nuclear ionic homeostasis was found to be dependent upon a tight crosstalk between receptors and ionic transporters of the plasma membranes and those of the nuclear membrane. This crosstalk seems to be the basis for excitation-contraction coupling, excitation-secretion coupling, and excitation - gene expression coupling. Further advancement in this field will certainly shed light on the role of nuclear membrane receptors and transporters in health and disease. This will in turn enable the successful design of a new class of drugs that specifically target such highly vital nuclear receptors and ionic transporters.     

Early fetal like slow Na+ current in heart cells of cardiomyopathic hamster

Using the whole-cell voltage-clamp technique, early embryonic tetrodotoxin (TTX) and Mn2⁺-insensitive slow Na⁺ current was detected in 10-22 week old fetal human heart cells as well as in 1-day-old and young cardiomyopathic hamster myocytes. This slow Na⁺ current in both heart cell preparations has the same kinetics and pharmacology. This type of slow Na⁺ current was absent in heart cells of newborn and young normal hamsters and became less present in myocytes of 19 and 22 week old human heart myocytes. Our results demonstrate that the slow Na⁺ channel does exist in early fetal human life and this type of channel continues to be functional after birth in myocytes of the hereditary cardiomyopathic hamster.     

Nuclear membrane receptors for ET-1 in cardiovascular function

Plasma membrane endothelin type A (ET(A)) receptors are internalized and recycled to the plasma membrane, whereas endothelin type B (ET(B)) receptors undergo degradation and subsequent nuclear translocation. Recent studies show that G protein-coupled receptors (GPCRs) and ion transporters are also present and functional at the nuclear membranes of many cell types. Similarly to other GPCRs, ET(A) and ET(B) are present at both the plasma and nuclear membranes of several cardiovascular cell types, including human cardiac, vascular smooth muscle, endocardial endothelial, and vascular endothelial cells. The distribution and density of ET(A)Rs in the cytosol (including the cell membrane) and the nucleus (including the nuclear membranes) differ between these cell types. However, the localization and density of ET-1 and ET(B) receptors are similar in these cell types. The extracellular ET-1-induced increase in cytosolic ([Ca](c)) and nuclear ([Ca](n)) free Ca(2+) is associated with an increase of cytosolic and nuclear reactive oxygen species. The extracellular ET-1-induced increase of [Ca](c) and [Ca](n) as well as intracellular ET-1-induced increase of [Ca](n) are cell-type dependent. The type of ET-1 receptor mediating the extracellular ET-1-induced increase of [Ca](c) and [Ca](n) depends on the cell type. However, the cytosolic ET-1-induced increase of [Ca](n) does not depend on cell type. In conclusion, nuclear membranes' ET-1 receptors may play an important role in overall ET-1 action. These nuclear membrane ET-1 receptors could be targets for a new generation of antagonists.     

Regulation of the calcium slow channel by cyclic GMP dependent protein kinase in chick heart cells

In order to assess the interaction between the cAMP-dependent and the cGMP-dependent phosphorylation pathways on the slow Ca²⁺ current (I_Ca(L)), whole-cell voltage-clamp experiments were conducted on embryonic chick heart cells. Addition of 8Br-cGMP to the bath solution reduced the basal (unstimulated) I_Ca(L). Intracellular application of the catalytic subunit of PK-A (PK-A(cat); 1.5 M) via the patch pipette rapidly potentiated I_Ca(L) by 215±16% (n=4); subsequent addition of 1 mM 8Br-cGMP to the bath reduced the amplitude of I_Ca(L) towards the initial control values (123±29%). Intracellular application of PK-G (25 nM pre-activated by 10^–7 M cGMP), rapidly inhibited the basal I_Ca(L) by 64±6% (n=8). Heat-denatured PK-G was ineffective. Subsequent additions of relatively high concentrations of 8Br-cAMP (1 mM) or isoproterenol (ISO, 1–10 M) did not significantly remove the PK-G blockade of I_Ca(L). The results of the present study suggest that: (a) 8Br-cGMP can inhibit the basal or stimulated (by PK-A(cat)) I_Ca(L) in embryonic chick myocardial cells. (b) PK-G applied intracellularly inhibits the basal I_Ca(L).     

The use of confocal microscopy in the investigation of cell structure and function in the heart,vascular endothelium and smooth muscle cells

In recent years, fluorescence microscopy imaging has become an important tool for studying cell structure and function. This non invasive technique permits characterization, localisation and qualitative quantification of free ions, messengers, pH, voltage and a pleiad of other molecules constituting living cells. In this paper, we present results using various commercially available fluorescent probes as well as some developed in our laboratory and discuss the advantages and limitations of these probes in confocal microscopy studies of the cardiovascular system.     

DNA antisense strategies in the study of receptors for vasoactive peptides,and of growth and wound-healing factors

Antisense oligodeoxynucleotide technology has contributed greatly to the overall understanding of both mRNA stability as well as translational processes leading to protein synthesis. Arrest of translational processes by DNA antisense strands usually reduces maximal effects of agonists without affecting their apparent affinities in treated isolated vascular or nonvascular preparations.In the present study, examples are given of DNA antisense oligonucleotide-induced repression of receptors for endothelins, kinins as well as of the platelet-derived growth factor. Furthermore, the efficiency of this technology illustrates the roles of protooncogenes (c-myc and c-myb) in wound-healing mechanisms.The overall mechanism of action of these oligomers is described and the relevance of size, chemical alterations and mode of delivery are illustrated. Release of oligophosphorothioates from polymer matrices and gels can produce a prolonged effect in vivo. Antisense oligonucleotides remain essential in experimental models for which receptor antagonists or selective inhibitors of intracellular components are currently unavailable.     

G-protein-coupled receptors, channels, and Na+-H+ exchanger in nuclear membranes of heart, hepatic, vascular endothelial, and smooth muscle cells

The action of several peptides and drugs is thought to be primarily dependent on their interactions with specific cell surface G-protein-coupled receptors and ionic transporters such as channels and exchangers. Recent development of 3-D confocal microscopy allowed several laboratories, including ours, to identify and study the localization of receptors, channels, and exchangers at the transcellular level of several cell types. Using this technique, we demonstrated in the nuclei of several types of cells the presence of Ca(2+) channels as well as Na(+)-H(+) exchanger and receptors such as endothelin-1 and angiotensin II receptors. Stimulation of these nuclear membrane G-protein-coupled receptors induced an increase of nuclear Ca(2+). Our results suggest that, similar to the plasma membrane, nuclear membranes possess channels, exchangers and receptors such as those for endothelin-1 and angiotensin II, and that the nucleus seems to be a cell within a cell. This article will emphasize these findings.