Evidence for the presence in smooth muscle of two types of Ca2+-transport ATPase

Membrane fractions prepared from smooth muscle of the pig stomach (antral part) contain two Ca2+-dependent phosphoprotein intermediates belonging to different Ca2+-transport ATPases. These alkali-labile phosphoproteins can be separated by electrophoresis in acid medium. The 130 kDa phosphoprotein resembles a corresponding protein in the erythrocyte membrane, whereas the 100 kDa protein resembles that of the Ca2+-transport ATPase in sarcoplasmic reticulum from skeletal muscle. These resemblances are expressed in terms of Mr, reaction to La3+ and in a similar proteolytic degradation pattern. The presence of the calmodulin-stimulated ATPase in mixed membranes from smooth muscle is confirmed by its binding of calmodulin and antibodies against erythrocyte Ca2+-transport ATPase, whereas such binding does not occur with proteins present in the presumed endoplasmic reticulum from smooth muscle.

Temporal appearance and distribution of the Ca2+ + Mg2+ ATPase of the sarcoplasmic reticulum in developing chick myocardium as determined by immunofluorescence labeling

The temporal appearance and distribution of the Ca2+ + Mg2+ ATPase of the sarcoplasmic reticulum were determined in the developing chick heart (stage 9 to stage 16) by indirect immunofluorescence labeling. The results obtained showed that the Ca2+ + Mg2+ ATPase was first observed in the bulbus ventricular region of the single tubular heart at stage 9 to 10 of development, when these myocardial cells first contract. As the atrial and later the sinus venosus tissues became incorporated into the single tubular heart the Ca2+ + Mg2+ ATPase was also observed in these regions, however, the highest density of Ca2+ + Mg2+ ATPase labeling was generally observed in the region of the heart most recently incorporated. These results suggest that the sarcoplasmic reticulum is present and perhaps functional in the regulation of the cytoplasmic Ca2+ concentration and thereby the contraction-relaxation cycle in myocardial cells when the first contraction occurs, as well as throughout all subsequent stages of development. Furthermore comparison between the relative density and intensity of the Ca2+ + Mg2+ ATPase labeling and the intrinsic rate of contraction of the myocardial cells in the various regions of the heart (A. Barry, 1942, J. Exp. Zool. 91, 119-130) supports the possibility that a positive correlation exists between these two characteristics of the myocardial cells.

Generation, characterization and ELISA of monospecific antibodies against the subunits of a Ca2+-dependent protein kinase and a Ca2+-transport ATPase from rabbit skeletal muscle

Monospecific precipitating sheep antibodies were generated for the first time against the purified, homogeneous alpha-, beta- and gamma-subunits of the Ca2+-dependent protein kinase, phosphorylase kinase, from rabbit muscle. As reference, antibodies against the holoenzyme and the CA2+-transport ATPase of sarcoplasmic reticulum were induced. In all cases antibody titers could be quantitated (standard error 5-10%) by enzyme-linked immunosorbent assay. Differentiation of antibody binding was achieved by quantitative precipitation and complement fixation assays. In general maximal antibody titers were reached 56 days after primary immunization and high titers (approximately 5000) were maintained for several weeks. Anti-alpha, anti-beta and anti-gamma avidly precipitate the denatured subunits employed as immunogens as well as the native enzyme. No cross-reactivity between antibodies against a specific subunit and any of the other heterologous subunits was demonstrable in double immunodiffusion assays providing no evidence for immunologically identical sites on the alpha-, beta- and gamma-subunits. Since anti-alpha, anti-beta and anti-gamma strongly inhibit enzyme activity, it is likely that they do so primarily by sterically interfering with the binding of the large substrate phosphorylase b (Mr 2.0 X 10(5)) to phosphorylase kinase (Mr 1.3 X 10(6)). It cannot be excluded, however, that anti-beta and anti-gamma bind to the active sites on these 2 subunits.

Localization of an intracellular membrane-bound Ca2+-ATPase in PtK-cells using immunofluorescence techniques

Monospecific antibodies to an intracellular membrane-bound Ca2+-ATPase were used to localize the enzyme in PtK-cells in interphase and in mitosis as well. In interphase the protein is distributed as small dots and rods in the cytoplasm with an increased concentration around the nucleus. Neither the plasma membrane nor the nuclear envelope are stained. In mitotic cells the Ca2+-ATPase is localized around the spindle rather than in it. The results are in agreement with the proposed function of enzyme as an essential part of the intracellular Ca2+-regulating system controlling Ca2+ in the respective domains of the cell.

Antibodies to the calmodulin-binding Ca2+-transport ATPase from smooth muscle

Antibodies were raised against a calmodulin-binding CaMg-ATPase (Ca2+-transport ATPase) from smooth muscle. The binding of these antibodies to a number of related Ca2+-transport ATPases was studied. Antibodies to the calmodulin-binding ATPase from porcine antrum (stomach) smooth muscle do not only bind to this CaMg-ATPase, but also to the corresponding enzyme in porcine erythrocytes. However, they do not bind to the CaMg-ATPase from sarcoplasmic reticulum of porcine skeletal muscle. The binding of these antibodies to the CaMg-ATPase of smooth muscle, does not inhibit the enzyme activity.

Polymorphism of myosin light chains. An electrophoretic and immunological study of rabbit skeletal-muscle myosins

Antibodies specific for rabbit fast-twitch-muscle myosin LCIF light chain were purified by affinity chromatography and characterized by both non-competitive and competitive enzyme-linked immunosorbent assay (ELISA) and a gel-electrophoresis-derived assay (GEDELISA). The antibodies did not cross-react with myosin heavy chains, and were weakly cross-reactive with the LC2F [5,5'-dithio-(2-nitrobenzoic acid)-dissociated] light chain and with all classes of dissociated light chains (LC1Sa, LC1Sb and LC2S), as well as with the whole myosin, from hind-limb slow-twitch muscle. The immunoreactivity of myosins with a truly mixed light-chain pattern (e.g. vastus lateralis and gastrocnemius) correlated with percentage content of fast-twitch-muscle-type light chains. A more extensive immunoreactivity was observed with diaphragm and masseter myosins, which were also characterized, respectively, by a relative or absolute deficiency of LC1Sa light chain. Furthermore, it was found that the LC1Sb light chain of masseter myosin is antigenically different from its slow-twitch-muscle myosin analogue, and is immunologically related to the LC1F light chain. Rabbit masseter muscle from its metabolic and physiological properties and the content, activity and immunological properties of sarcoplasmic-reticulum adenosine triphosphatase, is classified as a red, predominantly fast-twitch, muscle. Therefore our results suggest that the two antigenically different iso-forms of LC1Sb light chain are associated with the myosins of fast-twitch red and slow-twitch red fibres respectively.

Transitions in membrane composition during postnatal development of rabbit fast muscle

Early postnatal changes (4-5 days to 15 days after birth) in the biochemical composition of microsomes were investigated in rabbit skeletal muscles destined to become fast-twitch muscles. During this period, a steady decrease in the microsomal content of cholesterol and of ouabain-sensitive Na + /K + -ATPase activity, as well as a decrease in protein electrophoretic components in the 80 000-70 000 molecular weight range, were observed. These changes are probably due to a diminishing yield of microsomal membranes derived from T-tubules, as the age of the animals increases, and are indicated from a knowledge of the mixed composition of muscle microsomes and previous biochemical data on isolated T-tubules. The content of cytochrome b5, which was found to be high in muscle microsomes of newborn animals, decreased strikingly as the amount of membrane-bound Ca2 + -ATPase protein increased, with a crossing-over point at about 7-10 days after birth. These changes, possibly corresponding to a transition from precursor sarcoplasmic reticulum (SR) to mature SR, were found to be temporally correlated with changes in [3H] alpha-tocopherol binding ability of the microsomes and in the mitochondrial content of glycerol phosphate dehydrogenase. At the same critical periods, coincident with the onset of motile activity, the immunological cross-reactivity of the Ca2 + -ATPase protein of microsomal vesicles, with antibody specific for the Ca2 + -ATPase of adult fast SR, was found to increase markedly, as tested by competitive enzyme-linked immunosorbent assay (ELISA). The immunological data are consistent with data in the literature demonstrating an increase in the concentration of Ca2 + -ATPase molecules in the SR membranes during ontogenic development. Both these data and catalytic data, however, suggest that the Ca2 + -ATPase protein is present in the same form in the SR of immature and of adult fast muscle and, in an antigenically different form, in slow muscle SR.

Polymorphism of sarcoplasmic-reticulum adenosine triphosphatase of rabbit skeletal muscle

Antibody was raised in chickens against purified sarcoplasmic-reticulum Ca2+-activated ATPase (Ca2+-ATPase). The immunological relationship between the Ca2+-ATPase of fast-muscle and slow-muscle sarcoplasmic reticulum was investigated by a one-step and a two-step competitive enzyme-linked immunosorbent assay (ELISA). The results show marked antigenic differences between the membrane-bound Ca2+-ATPase of the sarcoplasmic-reticulum vesicles from fast muscle and slow muscle, beside differences in the membrane content of ATPase protein.