Effects of low temperature on contraction in papillary muscles from rabbit, rat, and hedgehog

During hibernation the body temperature may fall to only a few degrees above 0 degree C. The heart of the hedgehog continues to function whereas the hearts of nonhibernating mammals stop beating. The present study was performed to investigate and compare the mechanical responses to hypothermia in rabbits, rats, and hedgehogs. Isometric force was recorded from papillary muscles mounted in an organ bath and effects of hypothermia on the mechanical restitution curve were also compared. A reduction of bath temperature from 35 degrees C caused an increase in peak developed force. Maximum force was seen at 20 degrees C in the rabbit, 15 degrees C in the rat, and 10 degrees C in the hedgehog preparations. In all the species there was a similar prolongation of time to peak force and of time from peak to half-relaxation as temperature was lowered. An increase in resting force and after-contractions were recorded in the rabbit and rat muscles at temperatures below 15 and 10 degrees C, respectively. The rabbit and rat preparations became inexcitable at temperatures below 10 and 5 degrees C, respectively. The hedgehog papillary muscle, on the other hand, still contracted at 0 degree C and did not show increased resting force nor after-contractions. The results are consistent with the hypothesis that there is a calcium overload in cardiac cells from rabbit and rat at low temperatures but there is no calcium overload in the hedgehog muscle during hypothermia.     

Temperature effects on the Na and Ca currents in rat and hedgehog ventricular muscle

Cardiac transmembrane potentials and Na and Ca currents were recorded at different temperatures in rat and hedgehog ventricular muscle. At 35 degrees C in both species resting potential was about -80 mV and upstroke velocity (Vmax) of the action potential above 100 V/s. The shape of the action potential in hedgehog ventricular cells at 35 degrees C was similar to that in the rat showing a fast repolarization phase. When temperature was decreased, the membrane resting potential depolarized and action potential amplitude and Vmax declined. In rat ventricular cells at 10 degrees C, the resting potential was about -40 to -50 mV and Vmax was reduced to about 5 V/s. In hedgehog ventricular cells, however, the transmembrane potentials and Vmax were better maintained at low temperature. Phase 3 of the action potential was markedly prolonged below 20 degrees C in hedgehog but not in rat ventricular cells. When temperature was decreased to 10 degrees C the availability curve of the Na current shifted toward more negative potentials and ICa.peak declined in rat ventricular cells. In hedgehog cardiac preparations, the Na current was less influenced by the cooling and ICa.peak did not change very much at low temperatures. A transient inward current usually considered to induce cardiac arrhythmias could be recorded in rat ventricular cells below 20 degrees C but not in hedgehog preparations. These features of hedgehog cardiac membranes may contribute to the cold tolerance and the resistance to ventricular fibrillation during the hypothermia in mammalian hibernators.     

Mechanical alternans and restitution in failing SHHF rat left ventricles

We examined mechanical alternans and electromechanical restitution in normal and failing rat hearts. Alternans occurred at 5 Hz in failing versus 9 Hz in control hearts and was reversed by 300 nM isoproterenol, 6 mM extracellular Ca(2+), 300 nM -BAY K 8644, or 50 nM ryanodine. Restitution curves comprised phase I, which was completed before relaxation of the steady-state beat, and phase II, which occurred later. Phase I action potential area and developed pressure ratios were significantly reduced in the failing versus control hearts. Phase II was a monoexponential increase in relative developed pressure as the extrasystolic interval was increased. The plateau of phase II was significantly elevated in failing hearts. Thapsigargin (3 microM) plus ryanodine (200 nM) potentiated phase I to a significantly greater extent in control versus failing hearts and abolished phase II in both groups. The results suggest that both regulation of Ca(2+) influx across the sarcolemma and Ca(2+) release by the sarcoplasmic reticulum may contribute to altered excitation-contraction coupling in the failing spontaneously hypertensive heart failure prone rat heart.     

Phase I and phase II of short-term mechanical restitution in perfused rat left ventricles

We examined the contributions of the Ca(2+) channels of the sarcolemma and of the sarcoplasmic reticulum to electromechanical restitution. Extrasystoles (F(1)) were interpolated 40-600 ms following a steady-state beat (F(0)) in perfused rat ventricles paced at 2 or 3 Hz. Plots of F(1)/F(0) versus the extrasystolic interval consisted of phase I, which occurred before relaxation of the steady-state beat, and phase II, which occurred later. Phase I exhibited a period of enhanced left ventricular pressure development that coincided with action potential prolongation. Phase I was eliminated by -BAY K 8644 (100 nM) and FPL 64176 (150 nM), augmented by 3 microM thapsigargin plus 200 nM ryanodine and unaffected by KN-93 and KB-R7943. Phase II was accelerated by the Ca(2+) channel agonists and by isoproterenol but was eliminated by thapsigargin plus ryanodine. The results suggest that phase I of electromechanical restitution is caused by a transient L-type Ca(2+) current facilitation, whereas phase II represents the recovery of the ability of the sarcoplasmic reticulum to release Ca(2+).     

Histochemical fiber typing and staining intensity in cat and rat muscles.

In the gastrocnemius muscle of cat and rat, staining for oxidative enzymes differentiated three fiber types (A,B,C) and staining for adenosine triphosphate at pH 9.4 differentiated two fiber types (I, II) with a reliability of 90% and 98%, respectively. In cat 96% and in rat 90% of the fibers were typed identically after staining for nicotinamide adenine dinucleotidelinked lactic dehydrogenase (LDH) and succinic dehydrogenase (SDH). When differentiated by staining for LDH, A and B fibers were of type I. IN RAT, 80-90% OF ALL FIBERS WERE OF TYPE 22, COMPPRISING A, B and C fibers. Type I fibers stained for LDH intensely as did C fibers of type II, but stained intermediately for SDH. The degree of staining was measured by photometry. When fibers were stained for LDH, histograms of density showed three peaks corresponding to A, B and C fibers in cat, but only two peaks corresponding to A and C fibers in rat, In cat and rat, the densities of A, B and C fibers belonged to different populations. In soleus muscle of cat and rat stained for LDH, menadione-linked alpha-glycerophosphate dehydrogenase and adenosine triphosphatase at pH 9.4, the degree of staining differed from thatin any type of fiber in gastrocnemius muscle     

Chronotropic and inotropic dependence of the myocardium in patients with rheumatic heart disease before and after amiodarone treatment

Characteristic features of the electromechanical coupling of the myocardium were studied in patients with heart failure caused by rheumatic heart disease. Experiments were performed on muscle trabeculae isolated from the right atrial auricle in the course of surgical correction of a valve defect. The trabeculae displayed two types of mechanical responses, recorded in the isometric mode, to the postrest test. In the type I response, the mechanical restitution had an ascending pattern, the interval between electrical stimuli increasing. In type II, the mechanical restitution pattern was descending. Amiodarone (1 μM) treatment of the myocardium with the type I response enhanced the postrest potentiation of the mechanical response of trabeculae by more than 30%, but it had no effect on the muscles with the type II response. All patients whose biopsy material displayed the type II response had long episodes of atrial fibrillation. It is conceivable that the observed differences in the rhythm inotropic dependence of the human myocardium in rheumatic heart disease reflect different degrees of cardiomyocyte remodeling. The direction of this process is determined by the range of adaptive changes in intracellular structures, primarily, the sarcoplasmic reticulum.     

The sit-up: complex kinematics and muscle activity in voluntary axial movement.

This paper describes the kinematics and muscle activity associated with the standard sit-up, as a first step in the investigation of complex motor coordination. Eight normal human subjects lay on a force table and performed at least 15 sit-ups, with the arms across the chest and the legs straight and unconstrained. Several subjects also performed sit-ups with an additional weight added to the head. Support surface forces were recorded to calculate the location of the center of pressure and center of gravity; conventional motion analysis was used to measure segmental positions; and surface EMG was recorded from eight muscles. While the sit-up consists of two serial components, 'trunk curling' and 'footward pelvic rotation', it can be further subdivided into five phases, based on the kinematics. Phases I and II comprise trunk curling. Phase I consists of neck and upper trunk flexion, and phase II consists of lumbar trunk lifting. Phase II corresponds to the point of peak muscle contraction and maximum postural instability, the 'critical point' of the sit-up. Phases III-V comprise footward pelvic rotation. Phase III begins with pelvic rotation towards the feet, phase IV with leg lowering, and phase V with contact between the legs and the support surface. The overall pattern of muscle activity was complex with times of EMG onset, peak activity, offset, and duration differing for different muscles. This complex pattern changed qualitatively from one phase to the next, suggesting that the roles of different muscles and, as a consequence, the overall form of coordination, change during the sit-up.     

Distribution of sarcoplasmic reticulum Ca-ATPase and of calsequestrin in rabbit and rat skeletal muscle fibers

Muscle fibers in rabbit extensor digitorum longus (EDL), tibialis anterior (TA) and soleus, and rat soleus, were examined immunohistochemically for two proteins of the sarcoplasmic reticulum. Ca-ATPase and calsequestrin (CaS). Fibers were typed with the histochemical reaction for actomyosin ATPase. In the rabbit EDL and TA, type I fibers clearly reacted less for Ca-ATPase and CaS than type II fibers, but the difference was less with CaS than with Ca-ATPase. Although the differences were relatively small, IIB fibers consistently presented greater amounts of Ca-ATPase than IIA fibers. No type II subgroups could be recognized after incubation with anti-CaS. These findings confirm results from previous immunochemical measurements on whole muscles containing different proportions of IIA and IIB fibers (Leberer and Pette 1986). Type IIA and IIC in the rabbit and rat soleus reacted stronger for Ca-ATPase and for CaS than type I fibers. Small differences in Ca-ATPase, but not in CaS, were recognized within the type I fiber population. Therefore, type I fibers in the rabbit and rat soleus are not a homogeneous population.     

Endogenous protein kinase inhibitors. Purification, characterization, and distribution in different tissues.

A thermostable inhibition of ATP-protein phosphotransferase (EC 2.7.1.37) (protein kinase) which is present in crude tissue extracts has been resolved by gel chromatography (Sephadex G-100) into two molecular forms. These two forms will be referred to as type I and type II inhibitor. The type I inhibitor (Mr approximately or equal to 24,000) is specific for cAMP-dependent protein kinase and corresponds to the inhibitor described earlier (Walsh, D. A., Ashby, C. D., Gonzalez, C., Calkins, D., Fisher, E. H., and Krebs, E. G. (1971) J. Biol. Chem. 246, 1977-1985). The type II inhibitor (Mr approximately or equal to 15,000) competes for the enzyme with various substrate proteins (histone, alpha-casein, and Leu-Arg-Arg-Ala-Ser-Leu-Gly (kemptide). The type II inhibitor blocks protein phosphorylation catalyzed by several types of protein kinases (cAMP- and cGMP-dependent or cyclic nucleotide-independent protein kinases). The type II inhibitor from rat brain has been purified 1500-fold; this protein is thermostable, has acidic characteristics, and does not require Ca2+ ions for its activity. Different ratios and concentrations of type I and type II inhibitors of protein kinase are found in rat skeletal muscle, pancreas, cerebellum and corpus striatum, and in lobster tail muscle.     

Thermal phase transitions in sheep, rat and rabbit surfactant lipids detected by differential scanning calorimetry

1. The thermal behaviour of sheep, rat and rabbit pulmonary surfactant lipids was investigated using high sensitivity differential scanning calorimetry (DSC). 2. Phase transitions were evident in the surfactant lipids from all three animals, with the upper limit of the phase transition being 30.1 C in the sheep, 36.8 C in the rat and 36.3 C in the rabbit. 3. The relatively greater fluidity of the sheep surfactant lipids in comparison to those of the rat and rabbit was due primarily to differences in their palmitic acid content.     

Phase II jaw movements and masseter muscle activity during chewing in Papio anubis

It was proposed that the power stroke in primates has two distinct periods of occlusal contact, each with a characteristic motion of the mandibular molars relative to the maxillary molars. The two movements are called phase I and phase II, and they occur sequentially in that order (Kay and Hiiemae [1974] Am J. Phys. Anthropol. 40:227-256, Kay and Hiiemae [1974] Prosimian Biology, Pittsburgh: University of Pittsburgh Press, p. 501-530). Phase I movement is said to be associated with shearing along a series of crests, producing planar phase I facets and crushing on surfaces on the basins of the molars. Phase I terminates in centric occlusion. Phase II movement is said to be associated with grinding along the same surfaces that were used for crushing at the termination of phase I. Hylander et al. ([1987] Am J. Phys. Anthropol. 72:287-312; see also Hiiemae [1984] Food Acquisition and Processing, London: Academic Press, p. 257-281; Hylander and Crompton [1980] Am J. Phys. Anthropol. 52:239-251, [1986] Arch. Oral. Biol. 31:841-848) analyzed data on macaques and suggested that phase II movement may not be nearly as significant for food breakdown as phase I movement simply because, based on the magnitude of mandibular bone strain patterns, adductor muscle and occlusal forces are likely negligible during movement out of centric occlusion. Our goal is to better understand the functional significance of phase II movement within the broader context of masticatory kinematics during the power stroke. We analyze vertical and transverse mandibular motion and relative activity of the masseter and temporalis muscles during phase I and II movements in Papio anubis. We test whether significant muscle activity and, by inference, occlusal force occurs during phase II movement. We find that during phase II movement, there is negligible force developed in the superficial and deep masseter and the anterior and posterior temporalis muscles. Furthermore, mandibular movements are small during phase II compared to phase I. These results suggest that grinding during phase II movement is of minimal importance for food breakdown, and that most food breakdown on phase II facets occurs primarily at the end of phase I movement (i.e., crushing during phase I movement). We note, however, that depending on the orientation of phase I facets, significant grinding also occurs along phase I facets during phase I.     

Activation of protein kinase isozymes by cyclic nucleotide analogs used singly or in combination. Principles for optimizing the isozyme specificity of analog combinations

104 cAMP analogs, most of them modified in the adenine moiety, were tested as activators of cAMP-dependent protein kinase I (from rabbit or rat skeletal muscle) and kinase II (from bovine heart or rat skeletal muscle). When tested singly, only 2-phenyl-1,N6-etheno-cAMP showed a considerably (sevenfold) higher potency as an activator of kinase II than of kinase I. Analogs containing an 8-amino modification preferentially activated kinase I, some being more than 10-fold more potent as activators of kinase I than kinase II. When two analogs were combined, the concentration of one (complementary) analog required to half-maximally activate each isozyme was determined in the presence of a fixed concentration of another (priming) analog. Analogs tested in combination had been analyzed for their affinity for the intrasubunit binding sites (A, B) of isozyme I and II. The degree to which complementary analogs preferentially activated one isozyme was plotted against the mean site selectivity, i.e. (affinity A/B isozyme I X affinity A/B isozyme II) 1/2. This plot produced a straight line, the slope of which reflected the ability of the priming analog to discriminate homologous sites on the isozymes. This means that the isozyme discriminating power of an analog pair can be quantitatively predicted from the affinity of the analogs for site A and B of the two enzymes. It also means that a systematic analysis of those features of analogs imparting a high mean site selectivity or the ability to discriminate between homologous isozyme sites will facilitate the synthesis of new even more isozyme-selective analogs.     

Biochemical and immunological characterizations of rat pepsinogens and pepsins

Biochemical and immunological properties of two kinds of pepsinogens isolated from the gastric mucosal extracts of adult Wistar rats were studied. Their activated enzymes were prepared from the zymogens using a DEAE-Sepharose CL-6B column. The isoelectric points of pepsinogens I and II were estimated to be 3.90 and 3.75, respectively, by isoelectric focusing, and those of pepsins I and II to be 3.60 and 3.45, respectively. Amino acid compositions of the two pepsinogens or pepsins were strikingly similar to each other and neither pepsinogen I nor II contained organic phosphate. The biochemical properties of rat preparations compared with porcine pepsinogens A and C and pepsins A [EC 3.4.23.1] and C [EC 3.4.23.3] showed that rat pepsinogens and pepsins resembled porcine pepsinogen C and pepsin C, respectively. Pepsinogens I and II were demonstrated to share a similar immunogenic molecular structure by double diffusion analysis and Laurell immunoelectrophoresis. Rabbit antipepsinogen I serum cross-reacted with the mouse preparation but did not with the rabbit and porcine preparations. The possibility of the genetically controlled occurrence of pepsinogens I and II in the rat is discussed.     

The endothelin receptor antagonist, BQ-123, inhibits angiotensin II-induced contractions in rabbit aorta.

The purpose of this study was to examine the specificity of the cyclic pentapeptide ET(A) receptor antagonist BQ-123. BQ-123 competitively antagonized endothelin-1-induced contractions in rabbit aorta, increases in inositol phosphates in cultured rat vascular smooth muscle A10 cells, and binding of [125I]endothelin-1 to the cloned ETA receptor cDNA expressed in Cos 7 cells. In contrast, BQ-123 was a weak antagonist of [125I]endothelin-3 binding to rat cerebellar membranes and to membranes from Cos 7 cells transfected with the cloned ETB receptor cDNA. BQ-123 shifted concentration-response curves in isolated rabbit aorta elicited by angiotensin II, but did not bind to angiotensin II receptors nor affect angiotensin II-induced increases in inositol phosphates. BQ-123 also did not affect contractions induced by KCl or norepinephrine. These data suggest that endothelin may play a role in angiotensin II-induced contractions of rabbit aorta.     

Variability in LPS composition, antigenicity and reactogenicity of phase variants of Bordetella pertussis

Comparison of lipopolysaccharides (LPS) from phase variants of different strains of Bordetella phase variants of different strains of Bordetella pertussis has shown a difference in their composition, antigenicity and reactogenicity. Phase I variants of B. pertussis, with the exception of strain 134, contain a preponderance of LPS I whereas the major component of LPS of phase IV variants is LPS II. Sera raised to LPSs of phase I strains, other than 134, cross-react with each other but not with phase IV LPSs; and similarly all sera raised to phase IV LPSs cross-react with each other and with LPS from 134 phase I. The LPSs of all phase I variants, including that of 134, are approximately ten-fold or more reactive in the limulus amoebocyte lysate assay (LAL) than phase IV LPSs. In the human mononuclear cell pyrogen assay phase IV LPSs also stimulated a lower response than phase I LPSs. The B. pertussis phase I LPSs are 10-times more reactive than Escherichia coli standard endotoxin in the LAL assay but 100-times less reactive than E. coli LPS in the monocyte test for pyrogen. The SDS-PAGE profiles of B. pertussis LPSs are quite different from those of B. parapertussis and B. bronchiseptica strains. B. pertussis LPSs produced a typical lipo-oligosaccharide (LOS) pattern. B. bronchiseptica LPS produced a similar pattern but was antigenically distinct from B. pertussis LPSs I and II. B. parapertussis in contrast produced a ladder pattern typical of smooth type LPS.     

Generation of a fast and homogeneous temperature step

A method is described for the fast and homogeneous increase of the temperature of a biological specimen with a volume of 1 mm3 or less. Heating is obtained by joule dissipation from a 30 MHz alternating current. The step quality is determined by measuring the temporal and spatial behaviour of the temperature after a power pulse in and around the biological preparation. With the described equipment a temperature step of 3 degrees C can be obtained in 8 ms. The temperature step inhomogeneity is less than 15%. The compatibility of the method with electrophysiological and mechanical measurement and instrumentation is demonstrated by the detection of transients in transmembrane potential and force of a papillary muscle from the rabbit heart.     

Roles of troponin isoforms in pH dependence of contraction in rabbit fast and slow skeletal and cardiac muscles.

Skinned fibers prepared from rabbit fast and slow skeletal and cardiac muscles showed acidotic depression of the Ca2+ sensitivity of force generation, in which the magnitude depends on muscle type in the order of cardiac>fast skeletal>slow skeletal. Using a method that displaces whole troponin-complex in myofibrils with excess troponin T, the roles of Tn subunits in the differential pH dependence of the Ca2+ sensitivity of striated muscle were investigated by exchanging endogenous troponin I and troponin C in rabbit skinned cardiac muscle fibres with all possible combinations of the corresponding isoforms expressed in rabbit fast and slow skeletal and cardiac muscles. In fibers exchanged with fast skeletal or cardiac troponin I, cardiac troponin C confers a higher sensitivity to acidic pH on the Ca2+ sensitive force generation than fast skeletal troponin C independently of the isoform of troponin I present. On the other hand, fibres exchanged with slow skeletal troponin I exhibit the highest resistance to acidic pH in combination with either isoform of troponin C. These results indicate that troponin C is a determinant of the differential pH sensitivity of fast skeletal and cardiac muscles, while troponin I is a determinant of the pH sensitivity of slow skeletal muscle.     

Steered molecular dynamics studies of titin I1 domain unfolding

The cardiac muscle protein titin, responsible for developing passive elasticity and extensibility of muscle, possesses about 40 immunoglobulin-like (Ig) domains in its I-band region. Atomic force microscopy (AFM) and steered molecular dynamics (SMD) have been successfully combined to investigate the reversible unfolding of individual Ig domains. However, previous SMD studies of titin I-band modules have been restricted to I27, the only structurally known Ig domain from the distal region of the titin I-band. In this paper we report SMD simulations unfolding I1, the first structurally available Ig domain from the proximal region of the titin I-band. The simulations are carried out with a view toward upcoming atomic force microscopy experiments. Both constant velocity and constant force stretching have been employed to model mechanical unfolding of oxidized I1, which has a disulfide bond bridging beta-strands C and E, as well as reduced I1, in which the disulfide bridge is absent. The simulations reveal that I1 is protected against external stress mainly through six interstrand hydrogen bonds between its A and B beta-strands. The disulfide bond enhances the mechanical stability of oxidized I1 domains by restricting the rupture of backbone hydrogen bonds between the A'- and G-strands. The disulfide bond also limits the maximum extension of I1 to approximately 220 A. Comparison of the unfolding pathways of I1 and I27 are provided and implications to AFM experiments are discussed.     

Various critical comments on the interpretation of staircase- and potentiation phenomena in the rabbit heart muscle]

Some critical remarks on the interpretation of staircase and potentiation phenomena (rabbit heart muscle). Isometric contractions of rabbit papillary muscles and atrial strips were investigated at temperatures from 13.2 degrees C to 35 degrees C after rests of different duration at constant stimulation frequency before rest, in a period after rest and in a transition phase following a step of stimulation frequency. Changes in potentiation as well as changes in dynamics after rest and dynamics after steps of stimulation frequency are caused by lowering the temperature. Any hypothesis on the subject of Ca-movements between intracellular stores would have to account for changes in potentiation, staircase phenomena and the development of after-contractions at low temperatures.     

Polymorphism of alpha-actinin. Electrophoretic and immunological studies of rabbit skeletal muscle alpha-actinins

Heterogeneity of alpha-actinins from rabbit skeletal muscles was studied. Polyacrylamide gel electrophoresis in the presence and absence of sodium dodecyl sulfate has made it possible to distinguish two closely related alpha-actinins from rabbit fast, white muscle. One isoprotein (designated type I alpha-actinin) appears to be preferentially located in the psoas muscle, while the other (designated type II alpha-actinin) appears to be preferentially located in the longissimus dorsi muscle. Electrophoretic analyses have further shown that the two isoproteins are present as mixtures in most rabbit white, fast-twitch muscles. A standard polyacrylamide gel--sodium dodecyl sulfate/polyacrylamide gel sequential electrophoretic procedure was developed to resolve the different alpha-actinin dimers and to determine their subunit compositions. By this technique, both type I and type II alpha-actinins appeared to be homodimers. No heterodimeric species of alpha-actinin were detected. alpha-Actinin of red, slow-twitch muscles was similar to type II alpha-actinin of fast, white muscle on one-dimensional and two dimensional gels. However, slow, red muscle alpha-actinin was significantly different from fast, white muscle alpha-actinins in terms of one-dimensional peptide mapping and immunological cross-reactivity.