Beta-adrenergic receptor subtype-specific signaling in cardiac myocytes from beta(1) and beta(2) adrenoceptor knockout mice.

The sympathetic nervous system modulates cardiac contractility and rate by activating beta-adrenergic receptors (beta AR) expressed on cardiac myocytes and specialized cells in the sinoatrial node and the conduction system. Recent clinical studies have suggested that beta-adrenergic receptors also play a role in cardiac remodeling that occurs in the pathogenesis of cardiomyopathy. Both beta(1) and beta(2) adrenergic receptors are expressed in human and murine hearts. We have examined the effect of beta AR activation on the spontaneous contraction rate of neonatal myocyte cultures from wild-type and beta receptor knockout (KO) mice (beta(1)AR-KO, beta(2)AR-KO and beta(1)beta(2)AR-KO mice). Stimulation of the beta(1)AR in beta(2)AR-KO myocytes produces the greatest increase in contraction rate through a signaling pathway that requires protein kinase A (PKA) activation. In contrast, stimulation of the beta(2)AR in beta(1)AR-KO myocytes results in a biphasic effect on contraction rate with an initial increase in rate that does not require PKA, followed by a decrease in rate that involves coupling to a pertussis toxin sensitive G protein. A small isoproterenol-induced decrease in contraction rate observed in beta(1)beta(2)AR-KO myocytes can be attributed to the beta(3)AR. These studies show that all three beta AR subtypes are expressed in neonatal cardiac myocytes, and the beta(1)AR and beta(2)AR couple to distinct signaling pathways.

Spontaneous activation of beta(2)- but not beta(1)-adrenoceptors expressed in cardiac myocytes from beta(1)beta(2) double knockout mice.

Although ligand-free, constitutive beta(2)-adrenergic receptor (AR) signaling has been demonstrated in naive cell lines and in transgenic mice overexpressing cardiac beta(2)-AR, it is unclear whether the dominant cardiac beta-AR subtype, beta(1)-AR, shares the ability of spontaneous activation. In the present study, we expressed human beta(1)- or beta(2)-AR via recombinant adenoviral infection in ventricular myocytes isolated from beta(1)beta(2)-AR double knockout mice, creating pure beta(1)-AR and beta(2)-AR systems with variable receptor densities. A contractile response to a nonselective beta-AR agonist, isoproterenol, was absent in double knockout mouse myocytes but was fully restored after adenoviral beta(1)-AR or adenoviral beta(2)-AR infection. Increasing the titer of adenoviral vectors (multiplicity of infection 10-1000) led to a dose-dependent expression of beta(1)- or beta(2)-AR with a maximal density of 1207 +/- 173 (36-fold over the wild-type control value) and 821+/-38 fmol/mg protein (69-fold), respectively. Using confocal immunohistochemistry, we directly visualized the cellular distribution of beta(1)-AR and beta(2)-AR and found that both subtypes were distributed on the cell surface membrane and transverse tubules, resulting in a striated pattern. In the absence of ligand, beta(2)-AR expression resulted in graded increases in baseline cAMP and contractility up to 428% and 233% of control, respectively, at the maximal beta(2)-AR density. These effects were specifically reversed by a beta(2)-AR inverse agonist, ICI 118,551 (10(-7) M). In contrast, overexpression of beta(1)-AR, even at a greater density, failed to enhance either basal cAMP or contractility; the alleged beta(1)-AR inverse agonist, CGP 20712A (10(-6) M), had no significant effect on basal contraction in these cells. Thus, we conclude that acute beta(2)-AR overexpression in cardiac myocytes elicits significant physiological responses due to spontaneous receptor activation; however, this property is beta-AR subtype specific because beta(1)-AR does not exhibit agonist-independent spontaneous activation.

Amino acid sequence and embryonic expression of msr/apj, the mouse homolog of Xenopus X-msr and human APJ.

We have recently identified a new G protein-coupled receptor, X-msr, whose expression is associated with the endothelial lineage in Xenopus laevis (Devic, E., Paquereau, L., Vernier, P., Knibiehler, B., Audigier, Y., 1996. Expression of a new G protein-coupled receptor X-msr is associated with an endothelial lineage in Xenopus laevis. Mech. Dev. 59, 129-140). Based on its structural analogy to the human orphan receptor APJ, we cloned the murine msr/apj receptor and analyzed its expression in developing tissues. As observed for X-msr, msr/apj transcripts are detected in the endothelium of the primary blood vessels and the forming heart. In addition, they are expressed in somites, limb bud and branchial arches. This expression pattern is distinct from that of the Flk1 gene and suggests that the msr/apj gene is expressed in a subpopulation of endothelial precursors and a mesenchymal population derived from paraaxial mesoderm.

[Expression of a new family of receptors similar to CXC chemokine receptors in endothelial cell precursors]. / Expression d'une nouvelle famille de récepteurs apparentés aux récepteurs des CXC chémokines dans des précurseurs endothéliaux.

Characterization of a new family of G protein-coupled receptors is reported. Expression of these receptors is associated with endothelial lineage. Cloning of the Xenope X-msr receptor allowed to show that embryonic expression of this receptor occurred in the heart and developing primary blood vessels. Furthermore, within these cardiovascular structures, expression was restricted to the endothelial layer. Because structural similarities with the human orphan receptor h-APJ were found, the msr/apj receptor was cloned in mice. This showed that embryonic expression of this receptor was also confirmed to endothelial precursors. Thus, this receptor is the orthological equivalent in mice to the amphibian receptor X-msr. Molecular phylogenesis studies showed that the X-msr, msr/apj, and h-APJ receptors shared considerable homology with two CXC chemokine receptors, namely LCR1, whose name was recently changed to CXCR4, and RDC1, which is structurally similar to the CXCR2 receptor. The human h-APJ receptor is a co-receptor for entry of the HIV into T cells, a property associated only with CXC chemokine receptors in the lymphocyte population. These data suggest that this new signaling system may participate in endothelial precursor migration during developmental angiogenesis and in endothelial cell migration and proliferation during neoangiogenesis in adults.

Early expression of a beta1-adrenergic receptor and catecholamines in Xenopus oocytes and embryos.

From a Xenopus stage 11 cDNA library, we have cloned a gene, termed X-beta1AR, whose sequence is highly homologous to that of the human beta1-adrenergic receptor. As shown by RT-PCR assay, X-beta1AR RNA is present in the mature oocyte, decreases after fertilization up to stage 6 and then gradually increases during gastrulation. Binding studies performed with radiolabeled ligands reveal that X-beta1AR RNA is translated into the receptor protein. Furthermore, noradrenaline and adrenaline are also detected in oocytes and early embryos. The concomitant presence of beta1-adrenergic receptors and catecholamines suggest that this ligand-receptor couple could play a role in the very early stages of embryonic development.

Cloning and characterization of a cDNA encoding Xenopus laevis alpha o1 isoform of the Go protein.

The mammalian gene encoding the alpha subunit of the Go protein generates by alternative splicing two isoforms, alpha o1 and alpha o2, which differ in their carboxy-terminal region. We report here the cloning of a Xenopus cDNA (XG alpha o1) which encodes a protein corresponding to the mammalian alpha o1 isoform. In its 3' untranslated region, the transcript contains a repetitive motif made up of dinucleotide AT repeats. By RT-PCR amplification, we showed that XG alpha o1 transcripts are both maternal and zygotic. As alpha o2 transcripts have been shown to be maternal and devoid of AT repeats, the repetitive motif could play a role in the differential expression of each isoform.

Expression of a new G protein-coupled receptor X-msr is associated with an endothelial lineage in Xenopus laevis.

In order to determine whether G protein-coupled receptors play a role in early embryogenesis, we looked for cDNA fragments amplified between primers located in consensus sequences of transmembrane segments. Using one such amplified fragment as a probe, we cloned a novel member of the G protein-coupled receptor superfamily in Xenopus. Alignment of the deduced protein sequence with that of other receptors discloses some homology with angiotensin receptors. A single transcript of 2.5 kb is detected at the late blastula stage and its expression increases during gastrulation. In situ hybridization reveals transcripts initially in the ventrolateral involuting marginal zone and later in the lateral plate mesoderm. At larval stages, the transcript is expressed in procardiac tube and forming blood vessels, where it is localized in the inner endothelial layer. Thus, this gene traces an endothelial lineage and represents a very early and unique marker in Xenopus of the specification of cardiac and vascular endothelia. We propose the name of X-msr for mesenchyme-associated serpentine receptor.

The mRNA encoding a beta subunit of heterotrimeric GTP-binding proteins is localized to the animal pole of Xenopus laevis oocyte and embryos.

In order to provide evidence for a potential role of heterotrimeric GTP-binding proteins in the transduction of developmental signals, we prepared cDNAs from Xenopus laevis embryos and looked for fragments amplified between primers located in conserved sequences of the different subtypes of beta subunit. Using the amplified fragment as a probe, we cloned a member of the beta subunit family. The deduced protein sequence of the amphibian cDNA is highly homologous to the beta 1 subtype and, accordingly, we have named the Xenopus gene XG beta 1. In situ hybridization and RNase protection assay revealed that XG beta 1 mRNA is confined to the animal hemisphere of the mature oocyte. This localization of XG beta 1 mRNA is established at stage V during oogenesis. Following fertilization, the maternal mRNAs cosegregate with animal cells during cleavage stages. At gastrulation, transcripts are expressed in the dorsal ectoderm layer that will give rise to the central nervous system. Thus, XG beta 1 mRNA belongs to the small family of localized maternal mRNAs; as a transducing protein, its restriction to a subset of embryonic cells could mediate the distinct responsiveness which contributes to the patterning of the embryo.

Mutation of valine residue unique to alpha subunit of Gs abolishes activation.

We recently characterized a decapeptide sequence (residues 367-376) that is important for the membrane association of the activated alpha subunit of Gs. We report here that when this sequence is replaced by the cognate sequence of Gi1 alpha subunit, the chimeric protein (Gsis alpha) still interacts with the membrane but cannot be activated, regardless of the mode of activation. Construction of various chimeras demonstrates that the single replacement of valine 367 by threonine, the cognate residue of Gi1 alpha subunit, fully reproduces the loss of activation. Analysis of nucleotide interaction reveals that the mutant V367T Gs alpha protein poorly binds GDP or GTP. On the other hand, the conservative change of valine to isoleucine does not alter activation. Interestingly, members of the Gs and G12 classes have a valine and an isoleucine, respectively, at this position, whereas members of the Gi or Gq class contain a threonine residue. The evolutionary relationship between the different classes suggests that the presence of a hydrophobic or a hydrophilic residue is not fortuitous in these alpha subunits and might provide distinctive structural and/or functional properties.

Synchronous development of spontaneous and evoked calcium-dependent properties in hypothalamic neurons.

The development of various related parameters was compared in hypothalamic neurons grown in primary culture. We measured: (i) low- and high-voltage-activated calcium currents; (ii) spontaneous and N-methyl-D-aspartate (NMDA)-induced fluctuations of intracellular calcium concentration; (iii) basal and NMDA- or potassium-evoked somatostatin release. Spontaneous calcium fluctuations appeared after 5 days in culture and increased progressively in amplitude and frequency over the next 8 days studied. Basal release of somatostatin was not detectable in 3 day-old cultures and reached a plateau at day 5. Responses evoked by exogenous stimulations (voltage-activated calcium currents, agonist-induced intracellular calcium rise and somatostatin release) appeared early in culture, increased in amplitude during 7-10 days and then stabilized. We conclude that, in hypothalamic neurons, the main neuronal functions develop in synchrony over a limited period of time.

Dihydropyridines interact with calcium-independent potassium currents in embryonic mammalian sensory neurons.

Early embryonic sensory neurons have two K currents resembling delayed rectifier and transient K currents of mature neurons. However, in contrast to those of adult neurons, the embryonic currents can hardly be separated either by electrophysiological or pharmacological methods, limiting their characterisation at these developmental stages. Using the whole-cell recording technique, we found that dihydropyridines (DHPs) inhibit the noninactivating component of the Ca-independent K currents of 13-day mouse embryo dorsal-root ganglion (DRG) cells. The inhibitory effect of nicardipine began around 0.5 microM and was nearly complete at 5 microM while Na currents were not altered. This effect was reversible and voltage-dependent. The same results were obtained using another DHP Ca antagonist, nimodipine, whereas Bay K 8644, a DHP Ca agonist, had no effect. Kinetic properties of the DHP-insensitive K current have been described and compared with those of transient K currents found in differentiated neurons. These results suggest that both Ca and K channels have DHP sites, possibly homologous, at this developmental stage. The DHP inhibition of Ca-independent K channels provides a new tool with which to study K channels both at a molecular level and during DRG development.