Potential oxyradical damage and energy status in individual muscle fibres from degenerating muscle diseases

Inherited degenerating muscle diseases result in disintegration of muscle fibres, which is initiated by a lack of or alteration to a muscle protein. In Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) the protein is known to be dystrophin. The cellular function of dystrophin is not known in any detail but its absence appears to lead to a weakening of the sarcolemma. It has been proposed by Murphy and Kehrer that this leads ultimately to increased oxyradical production which may accelerate the degeneration. Studies have been carried out on individual muscle fibres derived from biopsy samples from patients with a number of degenerative muscle diseases. The glutathione cycling components, in particular glutathione and glutathione peroxidase, are significantly elevated in DMD, BMD and other diseases. Glutathione reductase is also elevated in some of these diseases. Energy producing systems are also affected particularly in intact fibres of muscle derived from muscle at an advanced stage of the disease. These results suggest that oxyradical damage may occur as a secondary consequence of muscle degenerating disease, leading to a breakdown in the glycogenolytic energy producing system.

Rapid isolation of rat brain nuclei on percoll gradients

A rapid isotonic method for fractionation of nuclei from rat brain is described. This procedure is based on the use of discontinuous colloidal silica gel (Percoll) gradients. We start from a 63,000-g purified nuclear pellet (fraction P3) isolated from gray matter and white matter separately. This is followed by fractionation of fraction P3 in an initial differential centrifugation step on five-step Percoll gradients producing six nuclear fractions designated 1, 2, 3 (gray matter) and 4, 5, 6 (white matter). Fractions 2, 4, and 5 obtained from this centrifugation are heterogeneous. These fractions are subfractionated further under isopycnic conditions using five-step Percoll gradients to yield subfractions 2b, 4b, and 5c. Three methods were used to characterize the nuclear types. First, light and electron microscopic examination was used to identify the nuclei in each preparation and to assess the purity of each preparation. Second, the activities of RNA polymerase I and II were monitored. Third, the protein/DNA ratios of the nuclear fractions were determined. Fraction 1 was enriched in neuronal nuclei; fractions 2b and 4b in astrocytic nuclei; and fractions 3, 5c, and 6 in nuclei of oligodendrocytes. RNA polymerase I and II activity was highest in fraction 1, which also displayed the highest protein/DNA ratio. Electron microscopy showed that the various classes of nuclei are congruent to 90% pure. Therefore, the procedure described here is suitable for obtaining highly purified neuronal and three types of glial nuclei from rat brain.

Duchenne muscular dystrophy and dystrophin: sequence homology observations

Duchenne muscular dystrophy (DMD) is a genetically transmitted disease characterized by progressive muscle weakness and usually leads to death. DMD results from the absence, deficiency or dysfunction of the protein dystrophin. Analysis of protein data bases, including homology alignments and domain recognition patterns, have located highly significant correlations between dystrophin and other calcium regulating proteins. In particular, a major portion of the dystrophin sequence has been found to contain repeating units of approximately 100 amino acid residues. These repeating units were found to exhibit significant homology to troponin I. Troponin I has been found to bind to the calcium binding proteins calmodulin and troponin C. The regions of highest homology were characterized by patterns of high localization of charged amino acids and thus could represent a possible calmodulin or troponin C surface accessible binding site. Since subcellular localization studies have indicated that dystrophin is associated with the triadic junction, these findings imply that dystrophin could be involved in controlling intracellular calcium homeostasis.

Dynamic cardiomyoplasty: clinical follow-up results

From 1985 to April 1990, 78 clinical dynamic cardiomyoplasty procedures were performed using the latissimus dorsi muscle stimulated with the Medtronic Cardiomyoplasty System. Indications for surgery were mostly ischemic and idiopathic dilated cardiomyopathies with patients in severe cardiac insufficiency (NYHA Class III and IV). Results of this multicenter study (11 centers) indicate that the dynamic cardiomyoplasty procedure can be transferred and reproduced in many centers with low perioperative mortality and that it improves the functional status of patients who survive the procedure. The survival rate suggests a long-term benefit (average implant time: 11.7 months). Although clinical functional improvement was reported, actual hemodynamic augmentations could not be clearly demonstrated under the protocol. Further studies of functional and hemodynamic parameters are necessary to determine if dynamic cardiomyoplasty is efficacious for a well-defined group of congestive heart failure patients. These points will be addressed in forthcoming studies.

Stimulation of myoblast proliferation in culture by leukaemia inhibitory factor and other cytokines

Significant stimulation of growth of myoblasts in culture is achieved by leukemia inhibitory factor (LIF). The optimum activity of this cytokine occurs at about 6 pM LIF. Interleukin-6 (IL-6) also stimulates cultured myoblasts but to a lesser degree than LIF and the effect is not maintained for extended culture periods. In addition, transforming growth factor-alpha (TGF-alpha) also increases the growth rate of myoblasts but only after a considerable lag phase. All 3 cytokines may be of value in the large scale production of myoblasts for use in the potential treatment of primary myopathies by injection of cultured myoblasts into diseased muscle to form genetically complete muscle fibres after fusion of the myoblasts in situ. Their potential use is enhanced in that at least under the conditions used here they do not stimulate fibroblast proliferation.

Brain MRI in obsessive-compulsive disorder

Magnetic resonance imaging (MRI) brain scans were performed on 12 patients with obsessive-compulsive disorder and 12 healthy controls. Measurements of the area of the head of the caudate nucleus, cingulate gyrus thickness, intracaudate/frontal horn ratio, and area of the corpus callosum did not differ between the two groups. These limited data do not support the presence of a consistent gross brain structural abnormality in obsessive-compulsive disorder. Further studies using other anatomic measurements and other brain structural imaging techniques are warranted.

Protein phosphorylation in intact superior cervical ganglion during regeneration

The incorporation of radioactive phosphate into proteins of both normal and regenerating superior cervical ganglion nerve of the rat is reported. Incorporation studies carried out by in vitro and in vivo methods are compared. In the in vitro method, excised intact ganglia or their homogenates were incubated in the presence of inorganic phosphate or ATP, respectively, under various conditions. Proteins were analyzed by gel electrophoresis followed by autoradiography, in which quantitative but not qualitative differences between regenerating and control cases were apparent. In the in vivo procedure, inorganic phosphate was injected into the living animal 4 h before removal of ganglia. At least fivefold more proteins became labeled in vivo than in vitro, whereas no similarity in the pattern of labeling between the two methods was observed. For example, the most heavily labeled protein in the in vivo method, tentatively identified as microtubule-associated protein-2, was not detected on autoradiograms of proteins labeled by the in vitro method. In this latter method, an 85-kDa species and growth-associated protein-43 were always labeled, and the extent of their phosphorylation was enhanced by the additional presence of phosphatidylserine and Ca2+, a result indicating that these labeled species are substrates of protein kinase C. The in vitro conditions also led to the labeling of proteins identified as alpha- and beta-tubulin. Comparison of the methods suggests that removal of the ganglion interferes with the function of protein phosphorylation systems and that this effect involves elements of the cytoskeleton.

The pathological damage in Duchenne muscular dystrophy may be due to increased intracellular OXY-radical generation caused by the absence of dystrophin and subsequent alterations in Ca2+ metabolism

Recent advances in the genetic and molecular pathogenesis of Duchenne muscular dystrophy and the evidence suggesting a role for oxygen free radicals (oxy-radicals) in the development of this disease are reviewed. In addition, we outline a working of hypothesis as to how disruptions in intracellular Ca2+ homeostasis within the dystrophic cell may initiate cycles of increased oxy-radical fluxes within these cells, leading to intracellular oxidative damage.

Phosphorylation of superior cervical ganglion proteins during regeneration

The incorporation of radioactive phosphate into proteins of both normal and regenerating ganglia of the sympathetic nervous system of the rat is reported. The incorporation reactions were carried out in vitro by incubating homogenates of excised ganglia with [gamma-32P]ATP under various conditions. It was found that incorporation of phosphate into proteins of regenerating ganglia in the molecular mass range 10,000-100,000 daltons increased up to 40% over incorporation into proteins from control ganglia during the first 3 days following injury and returned to control levels after 14 days. Analysis of the proteins by two-dimensional electrophoresis revealed that only few, i.e., less than 20, became radioactively labelled in homogenates of superior cervical ganglia in the presence of Ca2+, and even fewer in the presence of cyclic AMP. Furthermore, all these proteins fell within a narrow pI range of 4-6. The growth-associated protein, variously designated GAP-43, B-50, F-1, and pp46, has an enhanced level of expression and phosphorylation in regenerating ganglia compared with controls at day 3. Injury also caused consistently higher levels of incorporation into two other proteins with molecular masses at positions 55,000 and 85,000 and pI values of 5.1 and 4.5, respectively; the former protein most probably is beta-tubulin. The fact that both proteins are found in the 15,000 g pellet after the tissue has been solubilized in 0.5% nonionic detergent indicates that they may indeed by components of filament assemblies. Thus, the results suggest that protein phosphorylation is a mechanism involved in cytoskeletal function in regenerating nerve.

The binding of lipoproteins to human muscle cells: binding and uptake of LDL, HDL, and alpha-tocopherol

The specific binding of low-density lipoprotein (LDL) to cells and its subsequent uptake into these cells is well documented, but little is known of the LDL binding and uptake by skeletal muscle. Lipoproteins are the major transporters of tocopherols, deficiencies of which have been associated with a number of muscle diseases of animals. Their possible implication in human muscle diseases prompted our investigation of LDL and high-density lipoprotein (HDL) binding and uptake into human muscle cells in culture. Cultured human muscle cells were used at both the myoblast and myotube stage. They were incubated with LDL or HDL which were labelled by protein iodination or with (3H) alpha-tocopherol and receptor binding and cell uptake characteristics established. LDL binds to both myoblasts and myotubes, but the binding affinity increases significantly with the more highly differentiated cells. This binding appears to be specific to LDL receptors. The LDL is taken into the muscle cell and protein is degraded, as with other types of cells. HDL also binds to muscle cells, but there is no evidence of internalization. alpha-Tocopherol is transferred to muscle cells from both LDL and HDL, but the transfer is not dependent on lipoprotein internalization. HDL is effective as a means of transport of alpha-tocopherol to muscle cells, but LDL appears to be about one order more effective.

Micromethods in single muscle fibers. 2. Determination of glutathione reductase and glutathione peroxidase

This paper extends the previous study for systems which control intracellular oxidative events in muscle and describes procedures suitable to assay glutathione peroxidase (GSHPx), glutathione reductase (GR), and total glutathione (GSH + GSSG) after fiber typing of individual muscle fibers. In human skeletal muscle, both GR and GSHPx activities were relatively low when compared to those of other tissue. No difference was found among fiber types (I, IIA, and IIB) with regard to GR activity, but in contrast GSHPx activity was significantly lower in type IIB fibers than in the other types. These results suggest that type IIB fibers may have a reduced ability to cope with hydroperoxides generated during oxidative stress, which, in turn, could lead to increased damage to membrane structures by lipid peroxidation or oxidation of sensitive intracellular thiol (-SH) enzymes by hydrogen peroxide. The Km of skeletal muscle GR for GSSG was 27 microM and for NADPH was 22 microM. If one assumes approximately 95% of total glutathione is present in the reduced state, then GSSG concentration would be of the order of 0.3 mmol/kg and under these conditions skeletal muscle GR would be efficient in all muscle fiber types.

Micromethods in single muscle fibers. 1. Determination of catalase and superoxide dismutase

Methods have been developed for the measurements of catalase and superoxide dismutase (SOD) in single, isolated muscle fibers. These fibers are also classified according to fiber type. Catalase is determined using a fluorescent method for the measurement of hydrogen peroxide consumed. SOD measurements are carried out using a modification of established techniques whereby the inhibition of oxidation of epinephrine by SOD is assayed fluorometrically. Both enzymes may be determined in submicrogram samples of dried muscle. This approach avoids the complication of the inclusion of nonmuscle tissue with varying enzymatic activities which is frequently experienced when using homogenates of muscle, particularly diseased muscle. In addition, these techniques can be used to determine the inherent variation in SOD and catalase activities within individual fibers of the same fiber type. The Km and Vmax for catalase, determined using homogenates of human muscle, were found to be 12 mM and 1.45 mumol/min/mg dry wt, respectively. Catalase of muscle was inhibited 50% by 2 microM sodium azide. Mn-SOD contributes less than one-fifth of the total SOD activity. Therefore the activity is largely due to the Cu-Zn form of SOD. These methods are applicable to a wide variety of tissues.

The activity of neutral ribonucleases in nuclei of rat sympathetic ganglia and effects of nerve injury

Nuclei were isolated from homogenates of rat superior cervical ganglion by a conventional differential centrifugation technique with approximately 60% recovery. Ribonuclease activity at pH 7.1 (neutral ribonuclease) was associated with the "nuclei fraction" and represented 19% of the overall activity in normal ganglia. Ribonuclease in the "nuclei fraction" was stimulated variably by the sulfhydryl blocker N-ethylmaleimide indicating that a proportion was bound to the endogenous ribonuclease inhibitor present in these ganglia. The total activity of nuclear ribonuclease was increased 2-6 days after postganglionic nerve injury, such that the inhibitor-bound form of the enzyme increased maximally by 600% at day 4. The percentage of the total ganglionic activity in the "nuclei fraction" decreased in injured ganglia as a result of a rise in the activity of non-nuclear components. The changes in nuclear ribonuclease activity were distinct from those in the 850 g supernatant indicating that specific nuclear enzymes are being affected during regeneration.

The metabolic turnover of the major proteins of the postsynaptic density

We have used the method of Austin, Lowry, Brown and Carter, to measure the steady-state metabolic half-life of tubulin (alpha and beta individually) and actin (beta and gamma together) in the total cytosolic (S3), microsomal (P3), synaptic plasma membrane (SPM) and synaptic junction (SJ) subcellular fractions from 6-day-old and adult chicken forebrain. In the SPM and SJ fractions we also measured the steady-state metabolic half-life of the major postsynaptic density protein (mPSDp). In SPM and SJ fractions from 6-day-old chickens tubulin and actin turned over approximately twice as slowly (t1/2 approximately equal to 24 days) as tubulin and actin in the S3 fraction (t1/2 approximately equal to 13 days). This difference was unlikely merely to be due to association with membranes since the t1/2 values for the proteins were the same in P3 and S3. The estimated t1/2 values for mPSDp were similar to that for tubulin and actin in SPM and SJ fractions. Similar results were obtained in adult chickens except that all t1/2 values in all fractions were approximately 30% larger. The calculated t1/2 values did not change between labelling periods of 4 and 6.5 h suggesting that the lag phase of incorporation of newly synthesized PSD proteins is sufficiently rapid to not produce this result artefactually. When the brain from a non-labelled chicken was homogenized in the presence of the S3 fraction from a labelled chicken and sub-fractionated the relative specific activities of the SPM and SJ fractions produced were 1-2% of those from the labelled brain. These results support the notion that tubulin and actin are intrinsic components of the PSD.

Alkaline ribonuclease activity is increased in rat sympathetic ganglia after nerve injury

Ribonuclease activity at pH 7.1 ("alkaline" ribonuclease) was determined in homogenates of rat superior cervical ganglion up to 5 days after postganglionic nerve injury under optimal conditions of assay. Measurements were performed in the presence and absence of the sulfhydryl blocking agent, N-ethylmaleimide, to assess the proportion of "alkaline" ribonuclease apparently bound to endogenous inhibitor. Total ribonuclease activity per ganglion was stimulated 1.3 fold by 1 day after injury and remained elevated over the 5 day period. Free ribonuclease activity accounted for about 60% of the observed increase in total activity at day 1, but had returned to control level by day 3. At day 3 the entire 90% increase in total activity was attributable to ribonuclease bound to endogenous inhibitor (i.e. latent activity). These changes are occurring at times after nerve injury when marked alterations in RNA turnover have been observed, implicating "alkaline" ribonucleases in the control of RNA metabolism during nerve regeneration.

Ribonuclease activities in rat sympathetic ganglia: evidence for the presence of an endogenous inhibitor of alkaline ribonuclease

Using 3H-labeled rat brain mature RNA as substrate, substantial ribonuclease activity was detected in homogenates of rat superior cervical ganglia with acidic (pH 5.5) and neutral (pH 7.0-7.5) optima. Very little activity could be measured at greater than pH 8. The acidic and neutral activities differed in the optimal conditions required for assay, and showed differential sensitivity to the sulfhydryl blocking agent, N-ethylmaleimide. Only the neutral activity was stimulated, optimally by 2 mM N-ethylmaleimide, and the magnitude of stimulation indicated that the contributing ribonucleases exist largely in a latent form in the ganglion. Ribonucleases in other tissues with neutral pH dependence, known usually as "alkaline" ribonucleases, are subject to an N-ethylmaleimide-sensitive endogenous inhibitor protein. The existence of a similar inhibitor in rat superior cervical ganglia was indicated by the latency of neutral ribonuclease activity and confirmed by observing the effect of a soluble fraction from the ganglia on the activity of pancreatic ribonuclease A.

Axoplasmic transport of transfer RNA in the chick optic system

It has previously been shown that 4S RNA is transported in the optic nerve of the chick, but that no movement of rRNA can be detected. The 4S component behaved as though it were composed mainly of transfer RNA (tRNA), but the possibility remained that it could contain significant amounts of material resulting from RNA degradation. The transport of this 4S component has been examined in more detail to determine its nature. In addition, the transported material was examined to establish whether the transport of tRNA is a general phenomenon or that there are only a limited number of species involved. This was done using the same principles applied in the previous study; i.e., the specific activities of separated 4S RNA species appearing in the optic tectum 4 days after intraocular injection of [3H]uridine were compared with that of 5S RNA, a nontransported species. The separation was accomplished using 2.8-5-10-17% slab polyacrylamide gels, and 18 separate regions of 4S species could be identified. The results show that at least most, if not all 4S RNA species are transported. In a separate series of experiments the 4S RNA was aminoacylated and again separated on slab gels. In this instance, the RNA was labelled with [3H]uridine and the aminoacyl component with [14C]amino acids. Gel profiles of these dual-labelled components showed excellent correspondence between the two labels, demonstrating that 4S RNA species could be aminoacylated and were therefore tRNA species.(ABSTRACT TRUNCATED AT 250 WORDS)

A paradigm for axonal transport

Axonal transport has been extensively studied for a period of 20-30 years, but there is still no general consensus concerning the mechanism by which this transport process operates. An important development in this regard is the recent studies in the physical biochemistry group in the Department of Biochemistry at Monash University where it has been demonstrated that ordered flows may be generated spontaneously in polymer systems under non-equilibrium conditions. The new phenomenon exhibits many novel features, particularly with respect to polymer transport, which bear marked similarity to the behaviour of components in axonal transport. This article sets out to essentially bring to the attention of those in the neurosciences some of the properties of ordered structured flows in polymer solutions. These properties may generate a different view in the understanding of the mechanism of axonal transport.

Brief psychotherapy in late adolescence: a psychodynamic and developmental approach

Four cases were discussed in which college students presented themselves in crisis for psychiatric treatment; each was dealing with a normal developmental crisis of late adolescence centering around separation-individuation issues. A type of brief psychotherapy was described which maintained the focus on the primary dynamic conflict and promoted ego development by interpreting the unconscious intrapsychic conflict. The incestuous, aggressive, and regressive themes were explored, and defenses were actively interpreted whenever they interfered with the awareness of autonomous strivings consistent with the ego ideal. Although other authors have emphasized the necessity of establishing a contract early which specifies the number of visits, we have emphasized the importance of maintaining strict therapeutic neutrality, especially regarding the duration of treatment with late adolescents. We view this as an important cornerstone of technique in assisting the healthy late adolescent in his quest for increasing autonomy, ego-ideal integration and ego mastery.

Increased in vitro labeling of stable RNA within the rat nodose ganglion following abdominal vagotomy

An in vitro procedure for labeling of RNA in the excised rat nodose ganglion was used to evaluate the changes in incorporation of [3H]uridine into ganglionic RNA following transection of the abdominal vagus nerves. Significant increases in the incorporation into 28S, 18S and 4S RNA were observed at 1 day after injury, which were maximal at 4 days before returning to unoperated control level by 7 days. A second transient increase in the labelling of these RNA species occurred between 9 and 11 days after injury. Comparison of the time course of these increases with those seen previously following cervical vagus nerve crush injury indicate that the time of onset of the increase in incorporation in independent of the site of injury, but that the maximal response is delayed by 1 day with the more distal lesion. These data are consistent with the existence of separate signals for initiating and modulating the cell body response to axon injury, which are transported retrogradely from the site of injury at rates exceeding the slow component of axoplasmic transport.

Plasma lipoproteins in Duchenne muscular dystrophy

Plasma lipoproteins of Duchenne muscular dystrophy patients and carriers of the disease, together with age- and sex-matched controls, were examined by density gradient ultracentrifugation and agarose gel electrophoresis. Analysis of density gradient profiles revealed a significant reduction in absorbance (435 nm) by low density and high density lipoproteins from Duchenne patients when compared with controls. Although no abnormalities were observed on electrophoresis of whole plasma samples, the isolated low density lipoprotein fractions from Duchenne patients and carriers displayed increased electrophoretic mobility compared with controls. The results obtained implicate the plasma lipoproteins, in particular the low density lipoproteins, as the primary site of the lesion in this disease.

Thermodynamic behaviour of membrane enzymes in Duchenne muscular dystrophy

Erythrocyte ghost preparations have been prepared from blood of Duchenne patients (DMD), female carriers of the disease and controls. Arrhenius plots of Na+, K+-ATPase activity of these membrane preparations show a biphasic response for controls. For 75% of DMD and carriers the response is monophasic. This is not an inherent property of the membrane since it can vary over time in the one individual and it can be induced in normal membranes by preincubation with DMD plasma. Arrhenius plots of AChE activity showed no such difference between the three sources of blood.

Protein turnover in brain during the development of alcohol dependence

The chronic effect of ethanol on central nervous system protein turnover was investigated in selected regions of brain following intoxication and withdrawal in a strain of ethanol preferring mice. Mice were serially injected with [14C]glucose in order to achieve a constant specific radioactivity of brain glutamate. Protein turnover was calculated from the specific activities of extracted protein and free glutamate. Results from these studies show that ethanol causes a significant increase in protein turnover in all sections of brain. The brain protein turnover in animals following alcohol withdrawal also shows an increase which deviates significantly from controls in 2 of the 3 regions examined.