Observation of half-height magnetization steps in Sr2RuO4.

Spin-triplet superfluids can support exotic objects, such as half-quantum vortices characterized by the nontrivial winding of the spin structure. We present cantilever magnetometry measurements performed on mesoscopic samples of Sr(2)RuO(4), a spin-triplet superconductor. With micrometer-sized annular-shaped samples, we observed transitions between integer fluxoid states as well as a regime characterized by "half-integer transitions"--steps in the magnetization with half the height of the ones we observed between integer fluxoid states. These half-height steps are consistent with the existence of half-quantum vortices in superconducting Sr(2)RuO(4).

Enrichment of triadic and terminal cisternae vesicles from rabbit skeletal muscle.

An enriched triad and terminal cisternae preparation was achieved from skeletal muscle through alterations of the differential centrifugation and muscle homogenization protocols. Both yield and specific activity (pmoles of radioligand binding per mg protein) were optimized for (3)H-PN200-110 (transverse tubule marker) and (3)H-ryanodine (terminal cisternae marker) binding sites. By pelleting crude microsomes between 2,000 an 12,000 x g without any rehomogenizations, we improved both the yield and specific activity of transverse tubule and terminal cisternae markers in crude microsomes by approximately 4-fold to 1000-3000 pmoles binding sites (starting material: approximately 400 grams wet weight fast twitch skeletal muscle), with 10-15 pmoles/mg. Rehomogenization of the 1,000 x g pellet, which is typically discarded, allowed recovery of an additional 5000 pmoles PN200-110 binding sites and an additional 8000 pmoles ryanodine binding sites. Crude microsomes from the rehomogenized 1,000 x g pellets typically displayed specific activities of 20-25 pmoles binding/mg for both (3)H-PN200-110 and (3)H-ryanodine. Separation of crude microsomes on a sucrose gradient increased specific activity up to a maximum of 50 pmoles/mg in a specific fraction, a five- to ten-fold increase over standard triadic or terminal cisternae preparations. The mean specific activity for enriched triads was 30-40 pmoles/mg for both PN200-110 and ryanodine in pooled fractions, while pooled fractions of enriched terminal cisternae displayed low (3)H-PN200-110 binding (3-5 pmoles/mg) and high (3)H-ryanodine-specific activity (30-40 pmoles/mg).

Changes in gravitational force induce alterations in gene expression that can be monitored in the live, developing zebrafish heart.

Little is known about the effect of microgravity on gene expression, particularly in vivo during embryonic development. Using transgenic zebrafish that express the gfp gene under the influence of a beta-actin promoter, we examined the affect of simulated-microgravity on GFP expression in the heart. Zebrafish embryos, at the 18-20 somite-stage, were exposed to simulated-microgravity for 24 hours. The intensity of GFP fluorescence associated with the heart was then determined using fluorescence microscopy. Our measurements indicated that simulated-microgravity induced a 23.9% increase in GFP-associated fluorescence in the heart. In contrast, the caudal notochord showed a 17.5% increase and the embryo as a whole showed only an 8.5% increase in GFP-associated fluorescence. This suggests that there are specific effects on the heart causing the more dramatic increase. These studies indicate that microgravity can influence gene expression and demonstrate the usefulness of this in vivo model of 'reporter-gene' expression for studying the effects of microgravity.

Polylysine binding to unphosphorylated smooth muscle myosin enhances formation and stabilizes myosin filaments in vitro.

Previously, we demonstrated that positively charged polylysine, our model for biological polyamines, activates the Mg2+ ATPase activity of unphosphorylated smooth muscle myosin and shifts the myosin conformation from the folded 10S to linear 6S form. These effects of polylysine were reversed by the oppositely charged heparin (Szymanski et al. (1993) Am J Physiol 265, C379). In the present report, we provide further information on polylysine binding to smooth muscle myosin, and test the hypothesis that polylysine binding to unphosphorylated myosin involves filament formation. To relate the effects of polylysine on contractility in smooth muscle to physiologically relevant material, we investigated the ability of naturally occurring positively charged polyamines, histones, cadaverine, putrescine and spermidine to activate the Mg2+ ATPase activity of unphosphorylated smooth muscle myosin. Our data show that polylysine binding to individual unphosphorylated myosin molecules stimulates formation of myosin filaments. Polylysine also interacts with myosin filaments, causing enhancement of their size and the numbers, and this could be reversed by heparin. Polylysine binding to myosin filaments made them more resistant to disassembly by high salt concentrations (KCl) or ATP. Naturally occurring polyamines in millimolar concentrations activate the Mg2+ ATPase activity of unphosphorylated smooth muscle myosin. We suggest that the electrostatic interactions between naturally occurring positively charged polyamines and unphosphorylated smooth muscle myosin may play a role in stabilization of thick filament structurein situ.

Rescue of contractile parameters and myocyte hypertrophy in calsequestrin overexpressing myocardium by phospholamban ablation.

Cardiac-specific overexpression of murine cardiac calsequestrin results in depressed cardiac contractile parameters, low Ca(2+)-induced Ca(2+) release from sarcoplasmic reticulum (SR) and cardiac hypertrophy in transgenic mice. To test the hypothesis that inhibition of phospholamban activity may rescue some of these phenotypic alterations, the calsequestrin overexpressing mice were cross-bred with phospholamban-knockout mice. Phospholamban ablation in calsequestrin overexpressing mice led to reversal of the depressed cardiac contractile parameters in Langendorff-perfused hearts or in vivo. This was associated with increases of SR Ca(2+) storage, assessed by caffeine-induced Na(+)-Ca(2+) exchanger currents. The inactivation time of the L-type Ca(2+) current (I(Ca)), which has an inverse correlation with Ca(2+)-induced SR Ca(2+) release, and the relation between the peak current density and half-inactivation time were also normalized, indicating a restoration in the ability of I(Ca) to trigger SR Ca(2+) release. The prolonged action potentials in calsequestrin overexpressing cardiomyocytes also reversed to normal upon phospholamban ablation. Furthermore, ablation of phospholamban restored the expression levels of atrial natriuretic factor and alpha-skeletal actin mRNA as well as ventricular myocyte size. These results indicate that attenuation of phospholamban function may prevent or overcome functional and remodeling defects in hypertrophied hearts.

The alpha3 subtype of the nicotinic acetylcholine receptor is expressed in airway-related neurons of the nucleus tractus solitarius, but is not essential for reflex bronchoconstriction in ferrets.

To assess the role of nicotinic acetylcholine receptors (nACh-R) in the transmission of afferent constricting inputs from bronchopulmonary receptors to the nucleus tractus solitarius (nTS) and in the mediation of reflex airway constriction, we performed a combined immunohistological and functional study. In ferrets, the expression of nAch-R on the nTS neurons activated by histamine stimulation of airway sensory receptors was studied using laser scanning confocal microscopy to co-immunolocalize c-fos encoded protein (cFos) and nACh-R alpha3 subunit. We observed that activation of airway sensory receptors by inhalation of aerosolized histamine, induced cFos expression in a subset of nTS neurons that also expressed the nAch-R alpha3 subtype. Furthermore, activation of nACh-R within the commissural subnucleus by nicotine, increased cholinergic outflow to the airways. These effects were diminished by prior administration of hexamethonium (nACh-R blocker) within the commissural subnucleus of the nTS. However, hexamethonium had no significant effects on airway reflex constrictions induced by lung deflation. These findings indicate that nACh-R are expressed by the nTS neurons receiving inputs from airway sensory receptors, activation of which by nicotine increases cholinergic outflow to the airways, but the nACh-R pathways are not required for reflex bronchoconstriction.

Involvement of glutamate in transmission of afferent constrictive inputs from the airways to the nucleus tractus solitarius in ferrets.

In this study, we identified the neurons within nucleus tractus solitarius (nTS) activated by stimulation of airway sensory systems and examined the expression of AMPA receptor subtype(s) by these cells. We also investigated the possible involvement of endogenously released glutamate and AMPA receptors in the transmission of excitatory inputs from the sensory system of the respiratory tract to the neurons of the nTS. In these experiments we used: (1) immunodetection of c-fos encoded protein (cFos) expression to identify the nTS neurons activated by the stimulation of the airway sensory system; (2) receptor immunochemistry and confocal microscopy to determine the receptor(s) expressed by activated nTS neurons; (3) microdialysis to measure glutamate release, and (4) physiological measurements to examine the effects of selective receptor blockers, and thereby define the role of the glutamate and AMPA glutamatergic receptor subtype(s) in reflexly induced airway constriction. The results showed that activation of airway sensory receptors, by inhalation of aerosolized histamine or capsaicin, induced cFos expression in a subset of nTS neurons that also expressed the AMPA subtype of glutamate receptors. Furthermore, activation of sensory bronchoconstrictive receptors induced glutamate release within nTS, and blockade of the AMPA receptor subtype within nTS inhibited reflexly increased cholinergic outflow to the airways. These data indicate for the first time that glutamate and AMPA receptor signaling pathways are involved in the transmission of afferent inputs from the airways to the nTS, and in mediating reflex airway constriction.

Cardiac-specific overexpression of mouse cardiac calsequestrin is associated with depressed cardiovascular function and hypertrophy in transgenic mice.

Calsequestrin is a high capacity Ca2+-binding protein in the sarcoplasmic reticulum (SR) lumen. To elucidate the functional role of calsequestrin in vivo, transgenic mice were generated that overexpressed mouse cardiac calsequestrin in the heart. Overexpression (20-fold) of calsequestrin was associated with cardiac hypertrophy and induction of a fetal gene expression program. Isolated transgenic cardiomyocytes exhibited diminished shortening fraction (46%), shortening rate (60%), and relengthening rate (60%). The Ca2+ transient amplitude was also depressed (45%), although the SR Ca2+ storage capacity was augmented, as suggested by caffeine application studies. These alterations were associated with a decrease in L-type Ca2+ current density and prolongation of this channel's inactivation kinetics without changes in Na+-Ca2+ exchanger current density. Furthermore, there were increases in protein levels of SR Ca2+-ATPase, phospholamban, and calreticulin and decreases in FKBP12, without alterations in ryanodine receptor, junctin, and triadin levels in transgenic hearts. Left ventricular function analysis in Langendorff perfused hearts and closed-chest anesthetized mice also indicated depressed rates of contraction and relaxation of transgenic hearts. These findings suggest that calsequestrin overexpression is associated with increases in SR Ca2+ capacity, but decreases in Ca2+-induced SR Ca2+ release, leading to depressed contractility in the mammalian heart.

A-kinase anchoring protein 100 (AKAP100) is localized in multiple subcellular compartments in the adult rat heart.

Stimulation of beta-adrenergic receptors activates type I and II cyclic AMP-dependent protein kinase A, resulting in phosphorylation of various proteins in the heart. It has been proposed that PKA II compartmentalization by A-kinase-anchoring proteins (AKAPs) regulates cyclic AMP-dependent signaling in the cell. We investigated the expression and localization of AKAP100 in adult hearts. By immunoblotting, we identified AKAP100 in adult rat and human hearts, and showed that type I and II regulatory (RI and II) subunits of PKA are present in the rat heart. By immunofluorescence and confocal microscopy of rat cardiac myocytes and cryostat sections of rat left ventricle papillary muscles, we localized AKAP100 to the nucleus, sarcolemma, intercalated disc, and at the level of the Z-line. After double immunostaining of transverse cross-sections of the papillary muscles with AKAP100 plus alpha-actinin-specific antibodies or AKAP100 plus ryanodine receptor-specific antibodies, confocal images showed AKAP100 localization at the region of the transverse tubule/junctional sarcoplasmic reticulum. RI is distributed differently from RII in the myocytes. RII, but not RI, was colocalized with AKAP100 in the rat heart. Our studies suggest that AKAP100 tethers PKA II to multiple subcellular compartments for phosphorylation of different pools of substrate proteins in the heart.

Phospholamban ablation and compensatory responses in the mammalian heart.

Phospholamban is a low molecular weight phosphoprotein in cardiac sarcoplasmic reticulum. The regulatory role of phospholamban in vivo has recently been elucidated by targeting the gene of this protein in embryonic stem cells and generating phospholamban-deficient mice. The phospholamban knockout hearts exhibited significantly enhanced contractile parameters and attenuated responses to beta-agonists. The hyperdynamic cardiac function of the phospholamban knockout mice was not accompanied by any cytoarchitectural abnormalities or alterations in the expression levels of the cardiac sarcoplasmic reticulum Ca(2+)-ATPase, calsequestrin, Na(+)-Ca2+ exchanger, or the contractile proteins. Furthermore, the attenuation of the cardiac responses to beta-agonists was not due to alterations in the phosphorylation levels of the other key cardiac phosphoproteins in the phospholamban knockout hearts. However, ablation of phospholamban was associated with down-regulation of the ryanodine receptor, which suggests that a cross-talk between cardiac sarcoplasmic reticulum Ca2+ uptake and Ca2+ release occurred in an attempt to maintain Ca2+ homeostasis in these hyperdynamic phospholamban knockout hearts.

Ectopic expression of phospholamban in fast-twitch skeletal muscle alters sarcoplasmic reticulum Ca2+ transport and muscle relaxation.

There are three isoforms of the sarcoplasmic reticulum Ca2+-ATPase; they are known as SERCA1, SERCA2, and SERCA3. Phospholamban is present in tissues that express the SERCA2 isoform and is an inhibitor of the affinity of SERCA2 for calcium. In vitro reconstitution and cell culture expression studies have shown that phospholamban can also regulate SERCA1, the fast-twitch skeletal muscle isoform. To determine whether regulation of SERCA1 by phospholamban can be of physiological relevance, we generated transgenic mice that ectopically express phospholamban in fast-twitch skeletal muscle, a tissue normally devoid of phospholamban. Ectopic expression of phospholamban was associated with a decrease in the affinity of SERCA1 for calcium. Assessment of isometric twitch contractions of intact fast-twitch skeletal muscles revealed depressed rates of relaxation in transgenic mice compared with wild-type cohorts. Furthermore, the prolongation of muscle relaxation appeared to correlate with the levels of phospholamban expressed in two transgenic mouse lines. These findings indicate that ectopic expression of phospholamban in fast-twitch skeletal muscle is associated with inhibition of SERCA1 activity and decreased relaxation rates of this muscle.

Workload management in A&E: counting the uncountable and predicting the unpredictable.

The development of a workload management system for use in the accident and emergency department is described. The system is capable of capturing the work all professional groups, allowing the user to roster staff according to anticipated workload, and gives accurate information on whether staffing requirements are sufficient to provide the desired standard of care.

Desktop system for accounting, audit, and research in A&E.

The development of a database for audit, research, and accounting in accident and emergency (A&E) is described. The system uses a desktop computer, an optical scanner, sophisticated optical mark reader software, and workload management data. The system is highly flexible, easy to use, and at a cost of around 16,000 pounds affordable for larger departments wishing to move towards accounting. For smaller departments, it may be an alternative to full computerisation.

Norepinephrine-mediated calcium signaling is altered in vascular smooth muscle of diabetic rat.

We studied the influence of diabetes on norepinephrine (NE)-induced changes in intracellular free Ca2+ levels (receptor-mediated Ca2+ signaling) in single tail artery vascular smooth muscle (VSM) cells. VSM cells from 12-16 week streptozotocin-induced diabetic (SID) rats showed an increase in sensitivity to NE when compared to control VSM cells in that the concentration of NE needed to elicit half maximal response of the initial Ca2+ transient was reduced more than 4-fold though the maximal response attained was apparently reduced. In addition, the slope factor (steepness) of the dose-response relation was lowered 4-fold. Moreover, VSM cells of diabetic animals had a higher incidence of NE-induced Ca2+ oscillatory responses. The shift of the dose-response curve to the left, coupled with a higher incidence of oscillations, indicate that the noradrenergic receptor-mediated Ca2+ signaling pathways in tail artery VSM of diabetic rat may be altered.

Coordinate regulation of SR Ca(2+)-ATPase and phospholamban expression in developing murine heart.

Phospholamban, the regulator of Ca(2+)-adenosinetriphosphatase (ATPase) activity in cardiac sarcoplasmic reticulum (SR), is an important determinant of basal myocardial performance. To determine whether phospholamban expression is developmentally regulated in the mouse and whether such regulation reflects alterations in Ca2+ pump activity, hearts from different stages of development were processed for molecular biological and biochemical studies. Both phospholamban and Ca(2+)-ATPase mRNAs were approximately 40% of adult (100%) levels at birth and gradually increased to approach adult levels by day 15 of development. These changes in transcript levels were indicative of changes at the protein level for both phospholamban and Ca(2+)-ATPase. Analysis of the initial rates of Ca2+ uptake demonstrated that over the course of development the upregulation of Ca(2+)-ATPase correlated with increases in the maximal rates of Ca2+ uptake and the constant apparent stoichiometric ratio of phospholamban to Ca(2+)-ATPase correlated with maintenance of a constant affinity of this enzyme for Ca2+ (0.25 +/- 0.03 microM Ca2+). Furthermore, targeted ablation of phospholamban in the mouse resulted in a much higher affinity of Ca2+ uptake for Ca2+ (0.10 +/- 0.02 microM Ca2+) than that observed in wild-type hearts, and this increased affinity was also maintained across different stages of postnatal development. These findings suggest that phospholamban is a major regulator of the affinity of Ca(2+)-ATPase for Ca2+, and coordinate regulation of the expression levels of these two SR proteins may be necessary for maintaining Ca2+ homeostasis in the developing mammalian heart.

Phospholamban gene dosage effects in the mammalian heart.

Phospholamban ablation has been shown to result in significant increases in cardiac contractile parameters and loss of beta-adrenergic stimulation. To determine whether partial reduction in phospholamban levels is also associated with enhancement of cardiac performance and to further examine the sensitivity of the contractile system to alterations in phospholamban levels, hearts from wild-type, phospholamban-heterozygous, and phospholamban-deficient mice were studied in parallel at the subcellular, cellular, and organ levels. The phospholamban-heterozygous mice expressed reduced cardiac phospholamban mRNA and protein levels (40 +/- 5%) compared with wild type mice. The reduced phospholamban levels were associated with significant decreases in the EC50 of the sarcoplasmic reticulum Ca2+ pump for CA2+ and increases in the contractile parameters of isolated myocytes and beating hearts. The relative phospholamban levels among wild-type, phospholamban-heterozygous, and phospholamban-deficient mouse hearts correlated well with the (1) EC50 of the Ca(2+)-ATPase for Ca2+ in sarcoplasmic reticulum, (2) rates of relaxation and contraction in isolated cardiac myocytes, and (3) rates of relaxation and intact beating hearts. These findings suggest that physiological and pathological changes in the levels of phospholamban will result in parallel changes in sarcoplasmic reticulum function and cardiac contraction.

Immunolocalization of triadin, DHP receptors, and ryanodine receptors in adult and developing skeletal muscle of rats.

The dihydropyridine receptors (DHPR) and the ryanodine receptors (RyR) are well-characterized proteins of the triad junctions of skeletal muscle fibers. Recently, a newly discovered 95-kDa protein, triadin, has been purified from rabbit skeletal muscle heavy sarcoplasmic reticulum (SR) vesicles. WE have used indirect immunogold EM to localize triadin to the junctional face of the SR in isolated triads. In addition, we have used indirect immunofluorescence to localize triadin in relation to the DHPR and the RyR in adult and developing rat skeletal muscle. In double immunolabelling experiments of longitudinally oriented adult rat skeletal muscle tissue, triadin-specific and RyR-specific antibodies resulted in a characteristic striated staining pattern. The staining arising from these antibodies completely overlapped when examined by computer analysis of digitized laser scanning confocal microscopy images. A similar result was obtained in double staining experiments using antibodies raised against the DHPR and the RyR suggesting that all three proteins are located in the triads in situ. The developmental expression of the three triad proteins was examined using double labeling of skeletal muscle tissue from several fetal and early postnatal ages. The staining patterns of triadin, RyR, and DHPR antibodies were overlapping throughout development, suggesting that from their earliest appearance the three proteins are components of the triads.

Smooth muscle contractility is modulated by myosin tail-S2-LMM hinge region interaction.

The functional significance of two major smooth muscle myosin isoforms, which differ in the nonenzymic COOH-terminal tail region, is not known. We report here that a 13-amino acid peptide, which mimics a region of the tail unique to the SM1 myosin isoform, inhibits contraction velocity in permeabilized smooth muscle. This peptide is shown to bind to the S2-light meromyosin (LMM) hinge region of myosin using sodium dodecyl sulfate-polyacrylamide gel electrophoresis, photoaffinity labeling, and immunoelectron microscopy. Our results suggest that novel intermolecular contacts between the tail and S2-LMM hinge regions of adjacent myosin molecules in the thick filament may modulate contractility and provide a basis for distinct isoform function.

Molecular architecture of membranes involved in excitation-contraction coupling of cardiac muscle.

Peripheral couplings are junctions between the sarcoplasmic reticulum (SR) and the surface membrane (SM). Feet occupy the SR/SM junctional gap and are identified as the SR calcium release channels, or ryanodine receptors (RyRs). In cardiac muscle, the activation of RyRs during excitation-contraction (e-c) coupling is initiated by surface membrane depolarization, followed by the opening of surface membrane calcium channels, the dihydropyridine receptors (DHPRs). We have studied the disposition of DHPRs and RyRs, and the structure of peripheral couplings in chick myocardium, a muscle that has no transverse tubules. Immunolabeling shows colocalization of RyRs and DHPRs in clusters at the fiber's periphery. The positions of DHPR and RyR clusters change coincidentally during development. Freeze-fracture of the surface membrane reveals the presence of domains (junctional domains) occupied by clusters of large particles. Junctional domains in the surface membrane and arrays of feet in the junctional gap have similar sizes and corresponding positions during development, suggesting that both are components of peripheral couplings. As opposed to skeletal muscle, membrane particles in junctional domains of cardiac muscle do not form tetrads. Thus, despite their proximity to the feet, they do not appear to be specifically associated with them. Two observations establish the identify of the structurally identified feet arrays/junctional domain complexes with the immunocytochemically defined RyRs/DHPRs coclusters: the concomitant changes during development and the identification of feet as the cytoplasmic domains of RyRs. We suggest that the large particles in junctional domains of the surface membrane represent DHPRs. These observations have two important functional consequences. First, the apposition of DHPRs and RyRs indicates that most of the inward calcium current flows into the restricted space where feet are located. Secondly, contrary to skeletal muscle, presumptive DHPRs do not show a specific association with the feet, which is consistent with a less direct role of charge movement in cardiac than in skeletal e-c coupling.