Fred Schachat

Capillary density of skeletal muscle: A contributing mechanism for exercise intolerance in class II-III chronic heart failure independent of other peripheral alterations

OBJECTIVES The study was conducted to determine if the capillary density of skeletal muscle is a potential contributor to exercise intolerance in class II-III chronic heart failure (CHF). BACKGROUND Previous studies suggest that abnormalities in skeletal muscle histology, contractile protein content and enzymology contribute to exercise intolerance in CHF. METHODS The present study examined skeletal muscle biopsies from 22 male patients with CHF compared with 10 age-matched normal male control patients. Aerobic capacities, myosin heavy chain (MHC) isoforms, enzymes, and capillary density were measured. RESULTS The patients with CHF demonstrated a reduced peak oxygen consumption when compared to controls (15.0+/-2.5 vs. 19.8+/-5.0 ml x kg(-1) x min(-1), p <0.05). Using cell-specific antibodies to directly assess vascular density, there was a reduction in capillary density in CHF measured as the number of endothelial cells/fiber (1.42+/-0.28 vs. 1.74+/-0.35, p = 0.02). In CHF, capillary density was inversely related to maximal oxygen consumption (r = 0.479, p = 0.02). The MHC IIx isoform was found to be higher in patients with CHF versus normal subjects (28.5+/-13.6 vs. 19.5+/-9.4, p <0.05). CONCLUSIONS There was a significant reduction in microvascular density in patients with CHF compared with the control group, without major differences in other usual histologic and biochemical aerobic markers. The inverse relationship with peak oxygen consumption seen in the CHF group suggests that a reduction in microvascular density of skeletal muscle may precede other skeletal muscle alterations and play a critical role in the exercise intolerance characteristic of patients with CHF.

Effect of different troponin T-tropomyosin combinations on thin filament activation.

The response of permeabilized rabbit fast skeletal muscle fibers to calcium is determined by the troponin T (TnT) and tropomyosin (Tm) isoforms they express. Fibers expressing primarily TnT2f and alpha 2 Tm exhibit steeper pCa/tension relations than those in which either TnT1f or TnT3f and alpha beta Tm predominate. Troponin C extraction studies show that lower slopes do not result from a less concerted transition on the thin filament: the Tn-Tm regulatory strand activates as a unit in all fast fibers. Because the TnT variants differ in their N-terminal segments, and this region overlaps adjacent Tms on the regulatory strand, we propose that both the end-to-end overlap of Tm and the effect of TnT on that interaction are the basis of the concerted transition of the regulatory strand to the active state that occurs in the presence of calcium. Moreover, the effect of different Tn-Tm combinations on the ratio of the affinities of TnC for calcium in the relaxed and active states appears to be a significant determinant of the contractile properties of fast fibers in vivo.

Two homogeneous myosins in body-wall muscle of Caenorhabditis elegans

Abstract Myosin purified from the body-wall muscle-defective mutant E675 of the nematode. Caenorhabditis elegans, has heavy chain polypeptides which can be distinguished on the basis of molecular weight. On SDS-polyacrylamide gels, bands are found at 210,000 and 203,000 daltons. This is in contrast to myosin from the wild-type, N2, which has a single heavy chain band at 210,000 daltons. Both heavy chains of E675 are found in body-wall muscle (Epstein, Waterston and Brenner, 1974). When native myosin from E675 is fractionated on hydroxyapatite, it is separated into myosin containing predominantly one or the other molecular weight heavy chain and myosin containing a mixture of the heavy chains. Comparison of the CNBr fragments of myosin that contains predominantly 210,000 dalton heavy chains with those of myosin that contains predominantly 203,000 dalton heavy chains reveals multiple differences. These differences are not explained by the difference in molecular weight of the heavy chains, but may be explained if each type of heavy chain is the product of a different structural gene. Furthermore, because there are fractions which exhibit >80% 210,000 or >80% 203,000 dalton heavy chain, there is myosin which is homogeneous for each of the heavy chains. Although N2 myosin has only a single molecular weight heavy chain, it too is fractionated by hydroxyapatite. By comparing the CNBr fragments of different myosin fractions, we show that N2, like E675, has two kinds of heavy chains. E190, a body-wall muscle-defective mutant in the same complementation group as E675, is lacking the myosin heavy chain affected by the e675 mutation. This property has allowed us to determine by co-purification of labeled E190 myosin in the presence of excess, unlabeled E675 myosin that most, if not all, of the myosin that contains two different molecular weight heavy chains is due to the formation of complexes between homogeneous myosins and not to a heterogeneous myosin.

Myosins exist as homodimers of heavy chains: Demonstration with specific antibody purified by nematode mutant myosin affinity chromatography

Abstract The body-walls of Caenorhabditis elegans contain two different myosin heavy chains (Epstein, Waterston and Brenner, 1974) that associate to form at least two species of myosin (Schachat, Harris and Epstein, 1977a). To better define the distribution of these heavy chains in myosin molecules, we have characterized the myosin of C. elegans by immunochemical methods. Specific, precipitating anti-myosin antibody has been prepared in rabbits using highly purified nematode myosin as the immunogen. The difference in reactivity of the anti-myosin antibody with wild-type myosin containing both kinds of heavy chains (designated unc -54 and non- unc -54 heavy chains on the basis of genetic specification) and myosin from the mutant E190 that lacks unc -54 heavy chains Indicates that there are antigenic differences between myosin molecules containing unc -54 heavy chains and myosin molecules containing only non- unc -54 heavy chains. Antibody specific for the unc -54 myosin determinants has been prepared by the immunoadsorption of anti-myosin antibody with E190 myosin. This specific anti- unc -54 myosin antibody precipitates myosin that contains only unc -54 heavy chains. At the limits of resolution of our immunoprecipitation techniques, we could detect no heterodimeric myosin molecules containing both unc -54 and non- unc -54 heavy chains. The body-wall myosins of C. elegans therefore exist only as homodimers of either class of heavy chain. This specific anti- unc -54 myosin antibody promises to be a valuable tool in elucidating the role of two myosins in body-wall muscle and in molecular characterizations of mutant myosins in C. elegans. We report here the use of this antibody to detect antigenic differences between unc -54 myosin from the wild-type and the muscle mutant E675. In conjunction with the original anti-myosin antibody, other studies show that both unc -54 and non- unc -54 myosins exist within the same body-wall muscle cells (Mackenzie, Schachat and Epstein, 1978) and that both myosins are coordinately synthesized during muscle development in C. elegans (Garcea, Schachat and Epstein, 1978). We discuss the implications of the self-association of unc -54 and non- unc -54 myosin heavy chains into homodimeric myosins within the same body-wall muscles with respect to the assembly of thick filaments and their organization into a regular lattice.

The extent of amino-terminal heterogeneity in rabbit fast skeletal muscle troponin T

SummaryThe extent and nature of fast troponin T (TnT) heterogeneity has been assessed in rabbit skeletal muscle. Previous studies identified two major fast TnT species (TnT1f and TnT2f), in the fast white muscle erector spinae, differing in theirN-terminal cyanogen bromide (CNBr) fragments. Here a monoclonal antibody that recognizes a conserved region of TnT was used to characterize two additional TnT species (TnT3f and TnT4f) in the epaxial and limb musculature and a minor species (TnTcf) in craniofacial muscles. A combination of CNBr peptide mapping, immunoblotting and specific labelling of theN-terminus shows that these TnT species also differ in theirN-terminal region. This observation is consistent with cDNA studies that predicted theN-terminal region is hypervariable. One additional species, a variant of TnT2f present in the tongue, was identified by two-dimensional gel electrophoresis. The limited number of TnT variants indicates that the full potential for heterogeneity inferred from the cDNA studies is not realized. This conclusion is supported by immunoblot analysis with a monoclonal antibody that recognizes an epitope in the hypervariableN-terminal region which is present in all variants of TnT1f and TnT2f but absent from the lower molecular weight species TnT3f and TnT4f.

Immunocytochemical localization of two myosins within the same muscle cells in caenorhabditis elegans

Abstract Nematodes synthesize two major classes of myosin heavy chains. These heavy chains associate to form only homodimeric myosin molecules, and these myosin homodimers are anti-genically different from one another (Schachat, Garcea and Epstein, 1978). The two myosins may be designated unc -54 myosin, since this species is altered in mutants of the unc -54 locus, and non- unc -54 myosin, since this class is not affected in unc -54 mutants. We present here experiments in which specific anti-myosin IgG and anti- unc -54 myosin IgG are used to locate the two myosins within the same body-wall muscle cells of Caenorhabditis elegans. These results are necessary for further evaluation of the possible functions of the two myosin homodimers in the thick filaments of these muscles. Myosin can be localized to all body-wall and pharyngeal muscle cells using anti-myosin antibody. In longitudinal sections of body-wall muscle, the staining with anti-myosin coincides with the birefringence of A bands that contain thick filaments. Anti- unc -54 myosin stains all body-wall A bands uniformly but does not react with the pharynx. This result demonstrates that unc -54 is located exclusively in body-wall muscle cells of the wild-type strain N2. Non- unc -54 myosin is localized with anti-myosin in all body-wall muscle cells of the unc -54 null mutant E190, as expected; however, unc -54 myosin could not be detected by anti- unc -54 myosin antibody in this mutant. Since we can localize unc -54 myosin and non- unc -54 myosin in all body-wall muscle cells of wild-type and E190, respectively, we conclude that the two myosins must be present in the same muscle cells. In addition, since unc -54 myosin is located in all body-wall A bands, at least some sarcomeres must contain both myosins. This conclusion is consistent with the observations of Garcea, Schachat and Epstein (1978) that wild-type and E190 synthesize similar amounts of non- unc -54 myosin. Within the limits of resolution of our methods, unc -54 myosin is distributed throughout body-wall A bands. We conclude, therefore, that the majority of thick filaments within these A bands must contain unc -54 myosin along their entire length. Possible roles for unc -54 and non- unc -54 myosins in the assembly and organization of thick filaments are discussed.

Coordinate synthesis of two myosins in wild-type and mutant nematode muscle during larval development

Abstract In this paper we examine the role of two myosins in body-wall muscle cells of the nematode Caenorhabditis elegans. Large populations of nematodes are synchronized, and the synthesis and accumulation of myosin heavy chains and total protein are followed through postmitotic larval development. Growth is exponential with time for both the wild-type N2 and the body-wall muscledefective mutant E675, with a longer doubling time for the mutant. Utilizing the electrophoretic polymorphism of the E675 myosin heavy chains, we show that distinguishable classes of heavy chains accumulate differentially throughout development. Immunochemical measurements confirm a similar result in N2. Total myosin heavy chain accumulation is also quantitatively similar for the two strains. Myosin heavy chain relative synthetic rates as determined by pulse-labeling are constant throughout development and are equivalent for the two strains. The final fraction of accumulated unc -54 to total heavy chains of approximately 0.63 equals the constant synthetic fraction of approximately 0.62. Since myosin heavy chain accumulation and relative synthesis are equivalent, we conclude that the turnover of heavy chains is also similar in N2 and E675 despite the extensive structural and functional disruption within body-wall muscle cells of the latter strain. Since the accumulated fraction of unc -54 myosin heavy chains reaches a plateau at the constant synthetic fraction, myosin accumulation In the body-wall muscle cells may be attributed to a constant ratio of synthetic rates of the two body-wall myosin species. The coordinate synthesis of two myosins in the same body-wall muscle cells is discussed.

Expression of a novel combination of fast and slow troponin T isoforms in rabbit extraocular muscles

SummaryThe properties of extraocular muscles (EOMs) are quite different from those of the trunk and limb. Here we show that there is a novel pattern of troponin T (TnT) expression in EOMs which most likely contributes to the fine control of ocular movement and may reflect their innervation by cranial motoneurons. Three regions of the muscle were analysed to distinguish the TnT isoforms present in the fast singly-innervated fibres from those in the multiply-innervated fibres. More than 95% of the TnT in the singly-innervated fibres is TnT3f, which exhibits the most graded response to changes in calcium concentration during activation (Schachatet al., J. molec. Biol.198, 551–4). In multiply-innervated fibres, which exhibit tonic contractures, the slow troponin T TnT2s is expressed. While neither TnT3f nor TnT2s is unique to EOM, this pattern is unusual in two respects: first, both TnT3f and TnT2s are minor components of the trunk and limb musculature, and second, most muscles express several fast and both slow TnT species. Although EOM occupies a highly specialized physiological niche, its unusual physiology is not reflected in the presence of new TnT isoforms but in the expression of a different ratio of the known species of TnT.

Differential effects of exercise training in men and women with chronic heart failure

BACKGROUND Abnormalities of myosin heavy chain (MHC) isoforms, enzyme activity, and capillarity contribute to the exercise intolerance that is characteristic of patients with heart failure. To what extent these changes can be reversed with exercise training and whether differences exist in the responses of men and women remains uncertain. We described and compared the effects of exercise training on exercise capacity and skeletal muscle histochemistry in men and women with chronic heart failure. METHODS Fifteen patients (10 male) undergoing standard medical therapy completed a 14- to 24-week exercise training program. Peak oxygen consumption, MHC isoforms, capillary density, and selected metabolic enzymes were assessed before and after training. RESULTS Peak oxygen consumption was improved 14% (P <.05); however, this increase was mostly because of the improvement observed in men versus women (+20% versus +2%, respectively, P <.01). At baseline, MHC I content was lower in men than in women (33% +/- 3% vs 49.6% +/- 5.5%, P <.05). MHC I improved with training in men, to 45.6% +/- 4.5% (+38%, P <.05), versus women (-3%, P =.82), and the increase in men tended (P =.12) to be significant when compared with that in women. There were no significant changes in capillary density or muscle enzyme activity with training in the group as a whole or in men and women separately. CONCLUSION Among patients with chronic heart failure, improvements in peak exercise capacity may be more pronounced in men than in women. This difference in response of functional capacity to training paralleled differences observed between men and women for changes in MHC I isoforms.

Patterns of troponin T expression in mammalian fast, slow and promiscuous muscle fibres.

SummaryThe distribution of troponin T(TnT) species in typed single muscle fibres was analysed using one- and two-dimensional polyacrylamide gel electrophoresis (PAGE) and a monoclonal antibody specific for fast TnT. Fibres taken from erector spinae (Es), plantaris (Plt), diaphragm (Dia) and soleus (Sol) muscles of adult rabbits were pretyped as fast-twitch-glycolytic (FG), fast-twitch-oxidative-glycolytic (FOG), slow-twitch-oxidative (SO) or promiscuous (P) using a combination of histochemical staining and PAGE. Although none of the four size classes of TnT was either muscle or fibre type specific, their pattern of expression differed in each muscle and between the fibre types. FG fibres expressed TnT1f or TnT2f as predominant species, depending on the muscle; TnT3f and TnT4f were minor components. In contrast, all size classes of TnT were expressed in varying proportions in FOG fibres from Es and Plt, while those from Dia resembled FG fibres, expressing TnT1f as their major species. P fibres from Es, Plt, and Sol exhibited a distinctive pattern of fast TnT expression, TnT3f being the predominant species. Dia differed from the other muscles as TnT1f was the dominant fast TnT species in its P fibres as it is in the Dia fast fibres. Quantitative analysis of one- and two-dimensional gels revealed that the P fibres could be divided into two classes, those that exhibited discoordinate expression of fast and slow TnTs, myosin light chains and myosin heavy chains and those in which their expression was coordinate. In addition low levels of TnT4f were detected in SO fibres and of slow TnT in fast fibres.