Requirement of the Ca2+ channel ß2 subunit for sympathetic PKA phosphorylation.

Facilitation of cardiac function in response to signals from the sympathetic nervous system is initiated by the phosphorylation of L-type voltage-dependent Ca2+ channels (VDCCs) by protein kinase A (PKA), which in turn is activated by ß-adrenoceptors. Among the five subunits (α1, ß, α2/δ, and γ) of VDCCs, the α1 subunit and the family of ß subunits are substrates for PKA-catalyzed phosphorylation; however, the subunit responsible for ß-adrenergic augmentation of Ca2+ channel function has yet to be specifically identified. Here we show that the VDCC ß2 subunit is required for PKA phosphorylation upon sympathetic acceleration. In mice with ß2 subunit-null mutations, cardiac muscle contraction in response to isoproterenol was reduced and there was no significant increase in Ca2+ channel currents upon PKA-dependent phosphorylation. These findings indicate that within the sympathetic nervous system the ß2 subunit of VDCCs is required for physiological PKA-dependent channel phosphorylation.

Modified autonomic regulation in mice mutated in the ß4 subunit of the lh/lh calcium channel.

Genetic analyses have revealed an important association between P/Q-type calcium channel activities and hereditary neurological disorders. The P/Q-type channels are composed principally of heterologous multimeric subunits including CaV2.1 and CaVß4. Of these, the ß4 subunit is thought to play a significant role in channel physiology, because a mouse line mutant in that subunit (the lethargic mouse: lh) exhibits a severe ataxic phenotype. The aim of the present study was to elucidate the physiological importance of the ß4 subunit. ECG analysis showed that the T wave was high in 8-week-old lh mutants; this may be associated with hyperkalemia. Upon pharmacological ECG analysis, 2-3-week-old lh mutants exhibited reduced responses to a ß-blocker and a muscarinic receptor antagonist. Analysis of heart rate variability revealed that the R-R interval was unstable in lh mutants and that both the low- and high-frequency components had increased in extent, indicating that the tonus of both the sympathetic and parasympathetic nervous systems was modified. Thus, our present study revealed that the ß4 subunit played a significant role in regulation of sympathetic and parasympathetic nerve activities.

A novel binding site between the voltage-dependent calcium channel CaV1.2 subunit and CaVß2 subunit discovered using a new analysis method for protein-protein interactions.

We developed a new method to analyze protein-protein interactions using a dual-inducible prokaryotic expression system. To evaluate protein-protein binding, a chimeric fusion toxin gene was constructed using a DNase-treated short DNA fragment (epitope library) and CcdB, which encodes a DNA topoisomerase II toxin. Protein-protein interactions would affect toxin activity, resulting in colony formation. Using this novel system, we found a new binding site in the voltage-dependent calcium channel α1 subunit (CaV1.2) for the voltage-dependent calcium channel ß2 subunit. Prokaryotic expression screening of the ß2 subunit using an epitope library of CaV1.2 resulted in two overlapping clones of the C-terminal sequence of CaV1.2. In vitro overlay and immunoprecipitation analyses revealed preferential binding of the C-terminal sequences of CaV1.2 and ß2.

A simple, dual direct expression plasmid system in prokaryotic and mammalian cells.

We introduce a simple, dual direct cloning plasmid system (pgMAX-II) for gene expression analysis in both prokaryotic (Escherichia coli) and mammalian cells. This system, which uses a prokaryotic expression unit adapted from the pgMAX system and a mammalian promoter, is effective for subcloning using the DNA topoisomerase II toxin CcdB. Given that molecular biological cloning systems broadly rely on E. coli for rapid growth, the proposed concept may have wide applicability beyond mammalian cells.

Rapid method for plasmid DNA recombination (Murakami-system).

DNA recombination is a useful technology for cloning and subsequent functional analysis, while standard techniques for plasmid DNA recombination have remained unchanged. In the present study, we introduced rapid method for plasmid DNA recombination, which we named "Murakami-system", to complete the experiments in under 33 h. For this purpose, we selected the following: PCR amplification with 25 cycles and E. coli strain with rapid growth (incubation time of 6-8 h). In addition, we selected rapid plasmid DNA purification (mini-prep; ∼10 min) and rapid restriction enzyme incubation (20 min). This recombination system enabled rapid plasmid DNA recombination within 24-33 h, which could be useful in various fields. We also established a 1-day method for competent cell preparation. Our rapid recombination system allowed several sessions of plasmid DNA recombination to be performed every week, which improves the functional analysis of various genes.•"Rapid method for plasmid DNA recombination (Murakami-system).•E. coli strain with rapid growth (incubation time of 6-8 h).•Combination of rapid protocols (PCR, electrophoresis, DNA purification, ligation, and mini-prep) enabled plasmid DNA recombination within 24-33 h.

Enhanced ß-adrenergic response in mice with dominant-negative expression of the PKD2L1 channel.

Polycystic kidney disease (PKD) is the most common genetic cause of kidney failure in humans. Among the various PKD-related molecules, PKD2L1 forms cation channels, but its physiological importance is obscure. In the present study, we established a transgenic mouse line by overexpressing the dominant-negative form of the mouse PKD2L1 gene (i.e., lacking the pore-forming domain). The resulting PKD2L1del-Tg mice exhibited supraventricular premature contraction, as well as enhanced sensitivity to ß-adrenergic stimulation and unstable R-R intervals in electrocardiography. During spontaneous atrial contraction, PKD2L1del-Tg atria showed enhanced sensitivity to isoproterenol, norepinephrine, and epinephrine. Action potential recording revealed a shortened action potential duration in PKD2L1del-Tg atria in response to isoproterenol. These findings indicated increased adrenergic sensitivity in PKD2L1del-Tg mice, suggesting that PKD2L1 is involved in sympathetic regulation.

A dual prokaryotic (E. coli) expression system (pdMAX).

In this study, we introduced an efficient subcloning and expression system with two inducible prokaryotic expression promoters, arabinose and lac, in a single plasmid in Escherichia coli. The arabinose promoter unit allows for the expression of a FLAG-tagged protein, while the isopropyl-ß-D-thiogalactoside (IPTG)-inducible unit allows for the expression of a Myc-tagged protein. An efficient subcloning (DNA insertion) system (iUnit) follows each promoter. The iUnit, based on a toxin that targets DNA topoisomerase of E. coli, allows for effective selection with arabinose or IPTG induction. With the dual promoter plasmid (pdMAX) system, expressed lacZ (ß-galactosidase) activity was significantly decreased compared with the original solo expression system. Despite this disadvantage, we believe that the pdMAX system remains useful. A recombinant plasmid (pdMAX/ara/DsRed/IPTG/EGFP; pdMAX/DsRed/EGFP) with DsRed in the arabinose expression unit and EGFP in the IPTG expression unit showed fluorescent protein expression following additional low-temperature incubation. Thus, the novel pdMAX system allowed efficient subcloning of two different genes and can be used to induce and analyze the expression of two distinct genes. The proposed system can be applied to various types of prokaryotic gene expression analysis.

Attenuated ß-adrenergic response in calcium/calmodulin-dependent protein kinase IV-knockout mice.

In the present study, we examined the importance of Ca2+/calmodulin-dependent protein kinase IV (CaMKIV) in the regulation of cardiac function using genetically modified CaMKIV-null mice. RT-PCR analysis revealed decreased expression of voltage-dependent calcium channels in the cardiac myocytes of CaMKIV-null mice compared with wild-type mice. CaMKIV-null mice showed shortened QT time on electrocardiograms. Pharmacological analysis revealed decreased responsiveness to the ß-adrenergic blocker propranolol in CaMKIV-null mice, whereas the plasma norepinephrine level was not affected. CaMKIV-null mice showed decreased baroreflex on electrocardiograms. Heart rate variability analysis showed unstable R-R intervals, a decreased low frequency power/high frequency power (LF/HF) ratio, and increased standard deviation of the normal to normal R-R intervals (SDNN) in CaMKIV-null mice, suggesting decreased responsiveness to ß-adrenergic stimulation in CaMKIV-null mice. Atrial contraction analysis and cardiac action potential recording showed a decreased response to the ß-adrenoceptor agonist isoproterenol in CaMKIV-null mice. Furthermore, fluorescence imaging in a CRE-hrGFP assay revealed a decreased response to isoproterenol in CaMKIV-null cardiac myocytes. Taken together, our data strongly suggest a significant effect of CaMKIV gene ablation on cardiac ß-adrenergic signal transduction.

Decreased cardiac pacemaking and attenuated ß-adrenergic response in TRIC-A knockout mice.

Changes in intracellular calcium levels in the sinus node modulate cardiac pacemaking (the calcium clock). Trimeric intracellular cation (TRIC) channels are counterion channels on the surface of the sarcoplasmic reticulum and compensate for calcium release from ryanodine receptors, which play a major role in calcium-induced calcium release (CICR) and the calcium clock. TRIC channels are expected to affect the calcium clock in the sinus node. However, their physiological importance in cardiac rhythm formation remains unclear. We evaluated the importance of TRIC channels on cardiac pacemaking using TRIC-A-null (TRIC-A-/-) as well as TRIC-B+/-mice. Although systolic blood pressure (SBP) was not significantly different between wild-type (WT), TRIC-B+/-, and TRIC-A-/-mice, heart rate (HR) was significantly lower in TRIC-A-/-mice than other lines. Interestingly, HR and SBP showed a positive correlation in WT and TRIC-B+/-mice, while no such correlation was observed in TRIC-A-/-mice, suggesting modification of the blood pressure regulatory system in these mice. Isoproterenol (0.3 mg/kg) increased the HR in WT mice (98.8 ±â€…15.1 bpm), whereas a decreased response in HR was observed in TRIC-A-/-mice (23.8 ±â€…5.8 bpm), suggesting decreased sympathetic responses in TRIC-A-/-mice. Electrocardiography revealed unstable R-R intervals in TRIC-A-/-mice. Furthermore, TRIC-A-/-mice sometimes showed sinus pauses, suggesting a significant role of TRIC-A channels in cardiac pacemaking. In isolated atrium contraction or action potential recording, TRIC-A-/-mice showed decreased response to a ß-adrenergic sympathetic nerve agonist (isoproterenol, 100 nM), indicating decreased sympathetic responses. In summary, TRIC-A-/-mice showed decreased cardiac pacemaking in the sinus node and attenuated responses to ß-adrenergic stimulation, indicating the involvement of TRIC-A channels in cardiac rhythm formation and decreased sympathetic responses.

A simple and dual expression plasmid system in prokaryotic (E. coli) and mammalian cells.

We introduce a simple and universal cloning plasmid system for gene expression in prokaryotic (Escherichia coli) and mammalian cells. This novel system has two expression modes: the (subcloning) prokaryotic and mammalian modes. This system streamlines the process of producing mammalian gene expression plasmids with desired genes. The plasmid (prokaryotic mode) has an efficient selection system for DNA insertion, multiple component genes with rare restriction sites at both ends (termed "units"), and a simple transformation to mammalian expression mode utilizing rare restriction enzymes and re-ligation (deletion step). The new plasmid contains the lac promoter and operator followed by a blunt-end EcoRV recognition site, and a DNA topoisomerase II toxin-originated gene for effective selection with isopropyl-ß-D-thiogalactoside (IPTG) induction. This system is highly efficient for the subcloning of blunt-end fragments, including PCR products. After the insertion of the desired gene, protein encoded by the desired gene can be detected in E. coli with IPTG induction. Then, the lac promoter and operator are readily deleted with 8-nucleotide rare-cutter blunt-end enzymes (deletion step). Following re-ligation and transformation, the plasmid is ready for mammalian expression analysis (mammalian mode). This idea (conversion from prokaryotic to mammalian mode) can be widely adapted. The pgMAX system overwhelmingly simplifies prokaryotic and mammalian gene expression analyses.