Spectrophotometric determination of myoglobin in cardiac and skeletal muscle: separation from hemoglobin by subunit-exchange chromatography.

Myoglobin is extracted from muscle and separated from blood hemoglobin by subunit-exchange chromatography on a column of Sepharose 4B to which hemoglobin α-β subunits are linked covalently. Hemoglobin is retained on the column. Myoglobin in the effluent is determined spectrophotometrically as ferrous myoglobin or as carbon monoxide ferrous myoglobin. The method is applicable to cardiac, smooth, or skeletal muscle from mammals, reptiles, birds, and teleost fish, but failed with the one amphibian and the one shark tested.     

Embryonic synthesis of myoglobin in vivo estimated by radioimmunoassay

Chick embryos in ovo incorporated radioactivity from lysine-U-¹⁴C into myoglobin, as measured by an immunoprecipitation technique. The most consistent results were obtained by injection of the precursor into the yolk sac fluid.Incorporation, or apparent myoblobin synthesis, occurred in cardiac and skeletal muscle but not in liver, although incorporation of amino acid into total soluble proteins was equivalent in all tissues studied. Synthesis was highest in cardiac muscle and appeared there first in younger embryos. Myoglobin synthesis was detectable in the heart of embryos as early as 6 days of age and rose with age thereafter. Myoglobin synthesis appeared later and at lower levels in skeletal muscle.In vitro at neutral pH, tissue extracts of liver and muscle possessed only slight properties of myoglobin degradation.Using nonradioactive precipitin techniques, sensitive to 5–10 μg/ml, myoglobin was detected in embryonic heart muscle by week 2 of life and rose in content thereafter. Two of 8 embryos had trace amounts in thigh muscle near the time of hatching, and no embryos possessed measurable amounts of myoglobin in liver tissue or in pectoral skeletal muscle. Adult birds possessed equivalent amounts of myoglobin in heart and thigh muscle while pectoral muscle and liver tissue had no detectable myoglobin content.     

Determination of myoglobin concentration and oxidative capacity in cryostat sections of human and rat skeletal muscle fibres and rat cardiomyocytes

Myoglobin plays various roles in oxygen supply to muscle mitochondria. It is difficult, and in some cases impossible, to study the relationship between the myoglobin concentration and the oxidative capacity of individual muscle cells because myoglobin has to be fixed in situ whereas determination of oxidative capacity, for example, succinate dehydrogenase activity, requires unfixed cryostat sections. We have investigated whether a vapour-fixation technique allows the use of serial sections to study the relationship between myoglobin and succinate dehydrogenase activity. The technique is used to study a rat soleus muscle, two human skeletal muscle biopsies and biopsies of two patients with chronic heart failure, and in a control and hypertrophied rat heart. Staining intensities were quantified by microdensitometry. The absorbance values were calibrated using sections cut from gelatine blocks containing known amounts of myoglobin. The results show that it is possible to use serial sections for the determination of the myoglobin concentration and succinate dehydrogenase activity, and indicate that myoglobin can lead to a substantial reduction (18–60%) of the extracellular oxygen tension required to prevent an anoxic core in muscle cells.     

Myoglobin content and distribution in muscle tissues of Black Sea dolphins]

Myoglobin content is found to be higher in skeletal than in cardiac muscle of Tursiops truncatus and Phocaena phocaena and much higher than that in skeletal muscles of terrestrial mammals. According to the myoglobin content muscle fibres are devided into five types: red, white and three intermediate types. Deep muscles contain more red fibres and less intermediate fibres than superficial ones. White fibres compose almost one half of all fibres of the superficial skeletal muscles of the dolphins. The role of myoglobin distribution and higher content in oxygen supply of muscular tissue is discussed in relation to the peculiarities of dolphin breathing and blood circulation.     

Body size and skeletal muscle myoglobin of cetaceans: adaptations for maximizing dive duration

Cetaceans exhibit an exceptionally wide range of body mass that influence both the capacities for oxygen storage and utilization; the balance of these factors is important for defining dive limits. Furthermore, myoglobin content is a key oxygen store in the muscle as it is many times higher in marine mammals than terrestrial mammals. Yet little consideration has been given to the effects of myoglobin content or body mass on cetacean dive capacity. To determine the importance of myoglobin content and body mass on cetacean diving performance, we measured myoglobin content of the longissimus dorsi for ten odontocete (toothed whales) and one mysticete (baleen whales) species ranging in body mass from 70 to 80000 kg. The results showed that myoglobin content in cetaceans ranged from 1.81 to 5.78 g (100 g wet muscle)(-1). Myoglobin content and body mass were both positively and significantly correlated to maximum dive duration in odontocetes; this differed from the relationship for mysticetes. Overall, the combined effects of body mass and myoglobin content accounts for 50% of the variation in cetacean diving performance. While independent analysis of the odontocetes showed that body mass and myoglobin content accounts for 83% of the variation in odontocete dive capacity.     

Myoglobin in the heart tissue of fishes lacking hemoglobin

Myoglobin has been identified in the heart tissue of three species of antarctic icefish, Chaenocephalus aceratus, Pseudochaenichthys georgianus and Chaenodraco wilsoni. Quantitative analysis shows myoglobin concentrations that are substantially lower than other teleost fish. A simple and accurate method for the direct measurement of myoglobin in tissue is described.     

Myoglobinuria detection by capillary electrophoresis

Capillary electrophoresis was used in this study to separate urinary myoglobin from hemoglobin based on its electrophoretic mobility. Urine was applied directly without any treatment. The separation was accomplished in less than 7 min. Myoglobin extracted from human muscle tissues was separated, in a borate buffer 150 mM, pH 8.7 containing 0.5% polyethyleneglycol at 6 kV, into two peaks (MI and MII) which were also resolved far from hemoglobin. Upon standing at room temperature, MII converted into MI. Horse myoglobin eluted close to MI.The addition of polyethyleneglycol to the buffer enhanced the separation and increased the peak height of myoglobin. Optimum conditions for the separation are discussed. The method is suitable for routine clinical analysis because of its simplicity and speed.     

Meta-analysis of factors associated with omega-3 fatty acid contents of wild fish

Fish are recognized as the main source of physiologically important omega-3 long-chain polyunsaturated fatty acids, namely, eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA), for human nutrition. However, muscle tissue contents of these fatty acids in diverse fish species, i.e., their nutritive value for humans, varied within two orders of magnitude. We reviewed contents of EPA and DHA, measured by similar methods using an internal standard during chromatography as mg per g of wet mass in 172 fish species belonging to 16 orders, to evaluate probable variations in phylogenetic and ecological drivers. EPA + DHA content varied from 25.6 mg g^?1 of wet mass (Sardinops sagax) to 0.12 mg g^?1 (Gymnura spp.). Multidimensional redundancy analysis revealed that among phylogenetic, ecomorphological and abiotic environmental factors, the highest proportion of variation contribution belonged to the shared contribution of sets of phylogenetic and ecomorphological factors. Specifically, the highest values of EPA + DHA content were characteristic of fish belonging to the orders Clupeiformes or Salmoniformes, were pelagic fast swimmers, ate zooplankton and inhabited marine waters or migrated from fresh to marine waters (anadromous migrations). High EPA and DHA content in muscle tissues of the above species appeared to be a metabolic adaptation for fast continuous swimming. In contrast to common beliefs, our meta-analysis did not support the significant influence of higher trophic levels (piscivory) and cold environments (homeoviscous adaptation) on EPA and DHA content in fish. However, many causes of high and low levels of physiologically important fatty acids in certain fish species remained unexplained and require evaluation in future studies.     

Isolation and characterisation of myoglobin from the fresh water tortoise, Trionyx niloticus

Myoglobin was isolated from the skeletal muscle of the water tortoise, Trionyx niloticus. The myoglobin is monomeric with an apparent molecular weight of 18,000 daltons as determined on Sephadex G-75 (with a non-denaturing eluant) and 18,547 from the amino acid composition. Spectrophotometric characteristics for a variety of ferrous and ferric derivatives have been determined.     

Body oxygen stores, aerobic dive limits, and the diving abilities of juvenile and adult muskrats (Ondatra zibethicus)

Intraspecific variability in body oxygen reserves, muscle buffering capacity, diving metabolic rate, and diving behavior were examined in recently captured juvenile and adult muskrats. Allometric scaling exponents for lung (b=1.04), blood (b=0.91), and total body oxygen storage capacity (b=1.09) did not differ from unity. The concentration of skeletal muscle myoglobin scaled positively with mass in 254-600-g juveniles (b=1.63) but was mass-independent in larger individuals. Scaling exponents for diving metabolic rate and calculated aerobic dive limit (ADL) were 0.74 and 0.37, respectively. Contrary to allometric predictions, we found no evidence that the diving abilities of muskrats increased with age or body size. Juveniles aged 1-2 mo exhibited similar dive times but dove more frequently than summer-caught adults. Average and cumulative dive times and dive&rcolon;surface ratios were highest for fall- and winter-caught muskrats. Total body oxygen reserves were greatest in winter, mainly due to an increase in blood oxygen storage capacity. The buffering capacity of the hind limb swimming muscles also was highest in winter-caught animals. Several behavioral indicators of dive performance, including average and maximum duration of voluntary dives, varied positively with blood hemoglobin and muscle myoglobin concentration of muskrats. However, none of the behavioral measures were strongly correlated with the total body oxygen reserves or ADLs derived for these same individuals.     

The influence of the ratio of protein energy to total energy in the feed on the activity of protein synthesis in vitro, the level of ribosomal RNA and the RNA-DNA ratio in white trunk muscle of Atlantic cod (Gadus morhua)

Cod (Gadus morhua) were fed diets containing protein energy to total energy levels (PE/TE) of 10.0, 20.6, 29.6, 38.4, 56.2 and 74.1% for 21 days. Ribosomes were isolated from the white trunk muscle tissue, the capacity for protein synthesis in vitro determined and related to muscle tissue wet weight rRNA and DNA. Protein concentrations of less than 47.4% PE/TE in the diets reduce the ribosomal capacity for protein synthesis per g wet weight and per mg DNA, and the tissue contents of rRNA and ratio of rRNA/DNA. The capacity for muscle protein synthesis in vitro is a significant and sensitive parameter of protein inadequacy in fish diets.     

Dietary protein levels affect growth and protein metabolism in trunk muscle of cod,Gadus morhua

Summary Cod (Gadus morhua) of 50 g body weight were kept at 14°C. The fish were fed ad libitum during 80 days a diet containing protein levels which in terms of total energy corresponded to 25%, 45% or 65%. Growth increased in accordance with protein-energy levels. The protein content per gram of wet weight of white trunk muscle was unchanged, as was the myofibrillar protein myosin heavy chain determined by the antigen-antibody reaction of the enzyme-linked immunosorbent assay. The amount of messenger ribonucleic acid (mRNA) coding for myosin heavy chain was lower at 25% than at 45% or 65% protein-energy intake, the differences being significant per gram of wet weight of muscle. Acid proteinase activity was highest at the lowest protein-energy intake. Glycogen content in muscle increased with the protein-energy levels. It is concluded that the metabolic response of white trunk muscle to graded protein-energy intake included a change in the capacity to synthesize myosin heavy chain as judged by its mRNA content. The protein content per gram of wet weight was unaffected by dietary protein-energy levels of 25%, 45% and 65%, but protein accretion and thus growth of the animals increased with the protein intake. Dietary protein-energy restriction caused a rise in acid proteinase activity and a decrease in content of mRNA for myosin heavy chain, resulting in a diminished growth rate at an unchanged protein content per gram of wet weight of muscle.Abbreviations CTP cytidine triphosphate - DNA desoxyribonucleic acid - EDTA ethylenediaminetetra-acetic acid - mRNA messenger ribonucleic acid - TRIS tris(hydroxymethyl)aminomethane     

IN VITRO CULTURE OF MUSCLE TISSUE FROM NORMAL, HETEROZYGOUS, AND DYSTROPHIC CHICKS

The degree of histological deterioration of the original explant and the extent of cell spreading was evaluated in cultures of pectoralis muscle from 11-day chicks. Although the frequencies of these two parameters varied with the amounts of horse serum and embryo extract added to the medium, cultures from dystrophic chicks, in comparison to those from either normal or heterozygous animals, consistently showed the largest number of explants with the most extreme forms of histological deterioration and cell spreading. At 20 per cent horse serum the cultures from heterozygous chicks showed greater frequencies of the more extensive forms of deterioration and spreading than the normal muscle explants, but at 5 per cent horse serum these two groups appeared similar. Regardless of genetic background, cultures of the pectoralis muscle from 18-day embryos and of the latissimus dorsi muscle from 11-day chicks exhibited comparable high frequencies for the maximal degrees of deterioration and spreading.     

The myoglobin content in red, intermediate and white fibres of the swimming muscle sin three species of shark–a comparative study using high-performance liquid chromatography

A high-performance liquid chromatographic (HPLC) procedure is described for the determination of myoglobin in extracts of small samples of tissue from the three different fibre types in the swimming muscles of three species of sharks, Etmopterus spinax, Galeus melastomus and Scyliorhinus canicula . The method, which is based on the separation of myoglobin from haemoglobin from haemoglobin based on HPLC using a gel permeation chromatography column, has a detection limit of about 3 pmol myoglobin (Mb). In addition it has the added advantage of specific identification by its Soret band absorption and quantification. In all three species, the three fibre types of the muscle are completely separated and can be isolated at a high degree of purity. In red fibres the myoglobin content varied between 565 nmol mg⁻¹ wet weight ( Scyliorhinus ) and 170 nmol mg⁻¹ wet weight ( Galeus ). Intermediate fibres contained from 215 to 57, and white fibres from 11 to zero nmol mg⁻¹ wet weight. The myoglobin content is closely correlated to the vascularization as well as to the amounts of mitochondria in the different fibre types.     

Amino acid sequence of a myoglobin from lace monitor lizard, Varanus varius, and its evolutionary implications

Myoglobin was purified from a muscle extract of lace monitor lizard, Varanus varius, by Sephadex G-75, followed by DEAE-cellulose column chromatography. The apomyoglobin was cleaved with cyanogen bromide. The largest fragment was further digested with pepsin, trypsin, and alpha-chymotrypsin. From the amino acid sequence of the cyanogen bromide fragments, together with those of tryptic peptides of apomyoglobin, the complete amino acid sequence of lizard myoglobin was deduced. To investigate the tetrapod and amniote origins, many possible phylogenetic trees were constructed using the myoglobin sequences, including those of map turtle and lace monitor lizard. The tree that requires the minimum number of nucleotide substitutions in their genes for the myoglobin sequences to have evolved from a common ancestor was different from the similarly most parsimonious trees for cytochrome c or for alpha-hemoglobin. The trees were different from each other and from the tree that best reflects current biological opinions.     

DISTRIBUTION OF POLYSOMES IN MOUSE BRAIN TISSUE

Abstract— Polysomes were isolated from several different fractions of mouse brain tissue. After homogenization, the extract was centrifuged to yield a post-mitochondrial supernatant fraction and a pellet fraction. Sucrose gradient analysis of the material in the post-mitochondrial supernatant fraction indicated that 80 per cent of the ribosomes were present in polysomes and that little, if any, of the pellet fraction was present. Sucrose gradient analysis of the solution obtained after washing the pellet showed that very little polysomal material was present. The remaining pellet fraction was resuspended in a detergent mixture of deoxycholate-Tween 40. Sucrose gradient analysis of the resulting detergent-soluble solution indicated that large amounts of ribosomal material, in which 60–70 per cent of the ribosomes were associated in polysomes, were present.
In brain tissue from young animals, 20 per cent of the polysomes were found in the post-mitochondrial supernatant fraction whereas 80 per cent of the polysomes were released from the pellet fraction by detergent treatment. In contrast, in brain tissue from adult animals, 40 per cent of the polysomes were found in the post-mitochondrial supernatant fraction, whereas 60 per cent of the polysomes were released from the pellet fraction by detergent treatment.     

Myoglobin content and the activities of enzymes of energy metabolism in red and white fish hearts

Summary The myoglobin content of representative red and white coloured fish hearts was quantitated. It was confirmed that the macroscopic difference in appcarance is due to the presence or absence of myoglobin. Thereafter, the cytochrome c content as well as the maximal activities of key enzymes of energy metabolism were assessed in myoglobin-rich sea raven (Hemitripterus americanus) and myoglobin-poor ocean pout (Macrozoarces americanus) hearts. Both species are sluggish benthic dwellers that occur in similar habitats in the North Atlantic Ocean. The activities of enzymes associated with aerobic metabolism were similar in sea raven and ocean pout hearts, but far in excess of activities observed from white skeletal muscle. The two hearts also displayed comparable activities of enzymes associated with anaerobic energy metabolism. It therefore appears that the capacity to produce reducing equivalents for the electron transport system is similar in two selected fish hearts despite great differences in myoglobin content.