Myoglobin expression in L6 muscle cells. Role of differentiation and heme

Analysis of myoglobin levels in L6 cells (derived from rat skeletal muscle) by radioimmunoassay shows that myoglobin is not synthesized until after the cells differentiate to form multinucleated myotubes. Thereafter, myoglobin accumulates in a linear fashion for up to 20 days, the longest time for which the cultures may be reliably maintained. Treatment of cultures with hemin increased myoglobin levels in a dose-dependent manner resulting in a 70% increase in myoglobin with 20 microM hemin. Succinyl acetone, a heme synthesis inhibitor, reduced myoglobin levels by 40% while simultaneous treatment with hemin restored myoglobin levels to control values. Treatment of cultures with a variety of Fe(III) chelates known to enhance both iron accumulation and ferritin synthesis in L6 cells had no effect on myoglobin levels. delta-Aminolevulinic acid also had no effect on myoglobin levels. None of the treatments had any effect on either the total soluble protein or DNA content of the cultures, and, therefore, the observed effects appear to be specific for myoglobin. These results suggest that myoglobin is expressed as a function of differentiation and that intracellular heme exerts a regulatory effect on myoglobin levels.     

Antibodies against protein antigenic sites that are identical in the homologous protein of the immunized animal. Autoreactivity in rabbits of antibodies to sperm-whale myoglobin.

Sequence comparisons between the antigenic sites of sperm-whale myoglobin and the corresponding regions in rabbit myoglobin indicate that rabbits make antibodies to regions of the sperm-whale myoglobin molecule which are identical to the corresponding regions in rabbit myoglobin. Rabbit myoglobin did not precipitate with antisera to sperm-whale myoglobin. However, it exhibited an extensive cross-reaction as demonstrated by its ability to inhibit the precipitin reaction of sperm-whale myoglobin, and on an immunoadsorbent, bound a large amount of antibodies to sperm-whale myoglobin.     

The content of the chief amount of myoglobin in the blood serum as an immune complex

Pooled serum of health blood donors was tested for myoglobin and naturally occurring antibodies to myoglobin containing by competitive enzyme immunoassay. Data obtained show that myoglobin and autoantibodies of myoglobin are present in serum in the form of circulating immunocomplexes. Based on these results the suggestion about elimination of the main quantities of myoglobin by reticuloendothelial system is arisen. Estimated level of myoglobin concentration in the sera of health individuals established by different methods (80 ng/ml) is concerned apparently to free-circulated myoglobin and is not adequate to absolute myoglobin quantities.     

Adsorption of the protein antigen myoglobin affects the binding of conformation-specific monoclonal antibodies.

Five monoclonal antibodies against sperm whale myoglobin have been used to investigate the physical state of the antigen adsorbed onto a polydimethylsiloxane surface. The binding of each antibody is sensitive to the antigen's conformation in solution while the locations of the antigenic sites on the myoglobin molecule for three of the antibodies have been determined (Berzofsky, J.A., G.K. Buckenmeyer, G. Hicks, F.R.N. Gurd, R.J. Feldmann, and J. Minna. 1982. J. Biol. Chem. 257:3189-3198). The binding of the fluorescein isothiocyanate-labeled IgG and Fab antibodies to previously adsorbed myoglobin has been observed using total internal reflection fluorescence. Three of the antibodies bind specifically to surface-adsorbed myoglobin with affinities at least 50% relative to myoglobin in solution whereas two of the antibodies show affinities for the surface-adsorbed myoglobin diminished by at least two orders of magnitude relative to myoglobin in solution. The specific loss of certain antigenic determinants on the adsorbed myoglobin, coupled with the retention of others, indicates a nonrandom adsorption of the myoglobin molecules.     

Microdialysis separately monitors myocardial interstitial myoglobin during ischemia and reperfusion

Direct monitoring of myoglobin efflux during ischemia and reperfusion has been limited because of inherent sample collection problems in the ischemic region. Recently, the cardiac dialysis technique has offered a powerful method for monitoring myocardial interstitial levels of low-molecular-weight compounds in the cardiac ischemic region. In the present study, we extended the molecular target to high-molecular-weight compounds by use of microdialysis probes with a high-molecular-mass cutoff and monitored myocardial interstitial myoglobin levels. A dialysis probe was implanted in the left ventricular free wall in anesthetized rabbits. The main coronary artery was occluded for 60 or 120 min. We examined the effects of myocardial ischemia and reperfusion on myocardial interstitial myoglobin levels. Interstitial myoglobin increased within 15 min of ischemia and continued to increase during 120 min of ischemia, whereas blood myoglobin increased at 45 min of ischemia. Lactate and myoglobin in the interstitial space increased during the same period. At 60 min of ischemia, reperfusion markedly accelerated interstitial myoglobin release. The interstitial myoglobin level was fivefold higher at 0-15 min of reperfusion than at 60-75 min of coronary occlusion. The dialysis technique permits earlier detection of myoglobin release and separately monitors myoglobin release during ischemia and reperfusion. Myocardial interstitial myoglobin levels can serve as an index of myocardial injury evoked by ischemia or reperfusion.     

Predictability of weak binding from X-ray crystallography: inhaled anesthetics and myoglobin

Xenon and dichloromethane are inhalational anesthetic agents whose binding to myoglobin has been demonstrated by X-ray crystallography. We explore the thermodynamic significance of such binding using differential scanning calorimetry, circular dichroism spectroscopy, and hydrogen-tritium exchange measurements to study the effect of these agents on myoglobin folding stability. Though specific binding of these anesthetics might be expected to stabilize myoglobin against unfolding, dichloromethane actually destabilized myoglobin at all examined concentrations of this anesthetic (15, 40, and 200 mM). On the other hand, xenon (1 atm) stabilized myoglobin. Thus, dichloromethane and xenon have opposite effects on myoglobin stability despite localization in comparably folded X-ray crystallographic structures. These results suggest a need for solution measurements to complement crystallography if the consequences of weak binding to proteins are to be appreciated.     

The Role of H2O2-Generated Myoglobin Radical in Crosslinking of Myosin

The mechanism of myoglobin/H₂O₂ derived peroxidation of myosin was studied by comparing the catalytic activity of myoglobin and horseradish peroxidase using O-dianisidine, N-acetyl tyrosine and myosin as substrates. It was found that both hemoproteins induced myosin crosslinking and concomitant tyrosines oxidation to bityrosines, suggesting inter-molecular coupling of tyrosines in the crosslinking. The enzymatic activity of both hemoproteins on myosin was weak compared to small substrates. While horseradish peroxidase was much more active than myoglobin on small substrates, the reverse was true for myosin peroxidation. Since the suicidal interaction of myoglobin with H₂O₂ forms unstable tyrosine radicals, we suggest that the increased activity of myoglobin on myosin results from an efficient electron transfer between surface tyrosines of myosin and myoglobin but not horseradish peroxidase. These conclusions were supported by evidence that sperm whale myoglobin, which contains two active tyrosines -the heme-adjacent (tyrosine-103) and the surface (tyrosine-151), is more active as a mediator of myosin peroxidation than horse heart myoglobin which is devoid of the surface tyrosine.     

Crystallization and Physical Characterization of Porcine Myoglobin

Porcine myoglobin was isolated by fractionation with ammonium sulfate and crystallized with 3.8 M phosphate buffer.

Chromatography of the porcine crystalline myoglobin on a molecular-sieve column gave a single elution band, which agreed well with that of horse myoglobin.

By ultracentrifugal analysis, the sedimentation constant (s_20,w), was found to be 1.96 S.

The iron content of the myoglobin was 0.324%. This value corresponds to the minimal molecular weight of 17,200.

Absorption curves and millimolar extinction coefficients of the porcine myoglobin in several derivatives, namely, reduced (RMb), met (MMb), carboxy (MbCO) and cyanment (MMbCN) forms were examined in the visible region. The spectral characteristics of the porcine myoglobin derivatives were in good agreement with those of horse myoglobin,

Three components were detected for the porcine myoglobin by starch gel electrophoresis, and each of them had higher migration velocity than those of horse myoglobin.     

Participation of tyrosine residues of myoglobin in the disproportionateness reaction of heme iron (II) and (IV)]

By means of the comparison of the constant oxidation reactions of both the myoglobin modified by N-acetylimidazole and the intact myoglobin in the presence of H2O2 or ferrylmyoglobin we characterized the role of the tyrosine residues (Tyr) of myoglobin in the synproportionation reaction between heme iron (II) of one molecule and heme iron (IV)--of another. It was demonstrated that Tyr derivatization resulted in the decrease of the velocity of redox interaction between deoxymyoglobin (II) and ferrylmyoglobin (IV) and led to the decrease of the efficiency of oxymyoglobin deoxygenation. The effects were shown to be independent on Tyr quantity in myoglobin molecule and to have the same character for both the sperm-whale myoglobin and the horse myoglobin.     

The human myoglobin gene: a third dispersed globin locus in the human genome.

Human myoglobin is specified by a single gene. Unique sequence DNA probes were isolated from the cloned gene and used to test for the presence of the human myoglobin gene in a series of human rodent somatic cell hybrids containing various complements of human chromosomes. The myoglobin gene cosegregated with human chromosome 22. Somatic cell hybrids containing translocation chromosomes carrying part of chromosome 22 were used to locate the myoglobin gene to the region 22q11----22q13. The myoglobin gene is therefore not linked to the alpha-globin gene cluster on chromosome 16 or the beta-globin cluster on chromosome 11, and represents a third dispersed globin locus in the human genome.     

Electrochemical immunoanalysis of cardiac myoglobin

Methods of myoglobin determination based on electrochemical analysis by means of analysis of electrochemical parameters of modified electrodes have been proposed. The method of direct detection is based on interaction of myoglobin with anti-myoglobin with subsequent electrochemical registration of this hemoprotein. The electrode surface was modified by a membrane-like synthetic didodecyldimethylammonium bromide (DDAB), gold nanoparticles and antibodies to human cardiac myoglobin the electrochemical reduction of myoglobin heme was registered provided that the antigen (myoglobin) was present in the samples. The reaction of myoglobin binding to antibodies immobilized on the electrode surface was also registered using electrochemical impedance spectroscopy. The study of electro analytical characteristics revealed high specificity and sensitivity of the developed method. The biosensor was characterized by low detection limit and a high working range of the detected concentrations from 17.8 to 1780 ng/ml (from 1 to 100 nM). The method of myoglobin determination based on a signal of gold nanoparticles has also been proposed. The signal was detected with stripping voltammetry. There was a change in the cathodic peak area and the peak height of gold oxide reduction for the electrodes with antibodies and the electrodes with the antibody-myoglobin complex.     

Assessment of the functional diversity of human myoglobin

Myoglobin is presumably the most studied protein in biology. Its functional properties as a dioxygen storage and facilitator of dioxygen transport are widely acknowledged. Experimental evidence also implicates an essential role for myoglobin in the heart in regulating nitric oxide homeostasis. Under normoxia, oxygenated myoglobin can scavenge excessive nitric oxide, while under hypoxia, deoxygenated myoglobin can reduce nitrite, an oxidative product of nitric oxide, to bioactive nitric oxide. Myoglobin-driven nitrite reduction can protect the heart from ischemia and reperfusion injury. While horse and mouse myoglobin have been previously described to reduce nitrite under these conditions, a comparable activity has not been detected in human myoglobin. We here show that human myoglobin is a fully functional nitrite reductase. To study the role of human myoglobin for nitric oxide homeostasis we used repeated photometric wavelength scans and chemiluminescence based experiments. The results revealed that oxygenated human myoglobin reacts with nitrite-derived nitric oxide to form ferric myoglobin and that deoxygenated human myoglobin acts as a nitrite reductase in vitro and in situ. Rates of both nitric oxide scavenging and nitrite reduction were significantly higher in human compared to horse myoglobin. These data extend the existing knowledge about the functional properties of human myoglobin and are the basis for further translational studies towards the importance of myoglobin for nitric oxide metabolism in humans.     

The antibody response to myoglobin is independent of the immunized species. Analysis in terms of replacements in the antigenic sites and in environmental residues of the cross-reactions of fifteen myoglobins with sperm-whale myoglobin antisera raised in different species.

The recent determination of the entire antigenic structure of sperm-whale myoglobin with rabbit and goat antisera has permitted the examination of whether the antigenic structure recognized by antibodies depends on the species in which the antisera are raised. Also, by knowledge of the antigenic structure, the molecular factors that determine and influence antigenicity can be better understood in terms of the effects of amino acid substitutions occurring in the antigenic sites and in the environmental residues of the sites. In the present work, the myoglobins from finback whale, killer whale, horse, chimpanzee, sheep, goat, bovine, echidna, viscacha, rabbit, dog, cape fox, mouse and chicken were examined for their ability to cross-react with antisera to sperm-whale myoglobin. By immunoadsorbent titration studies with radioiodinated antibodies, each of these myoglobins was able to bind antibodies to sperm-whale myoglobin raised in goat, rabbit, chicken, cat, pig and outbred mouse. It was found that the extent of cross-reaction of a given myoglobin was not dependent on the species in which the antisera were raised. This indicated that the antibody response to sperm-whale myoglobin (i.e. its antigenic structure) is independent of the species in which the antisera are raised and is not directed to regions of sequence differences between the injected myoglobin and the myoglobin of the immunized host. Indeed, in each antiserum from a given species examined, that antiserum reacted with the myoglobin of that species. The extent of this auto-reactivity for a given myoglobin was comparable with the general extent of cross-reactivity shown by that myoglobin with antisera raised in other species. The cross-reactivities and auto-reactivities (both of which are of similar extents for a given myoglobin) can be reasonably rationalized in terms of the effects of amino acid substitutions within the antigenic sites and within the residues close to these sites. These findings confirm that the antigenicity of the sites is inherent in their three-dimensional locations.     

Testosterone stimulates myoglobin expression in different muscles of the mouse

The regulation of energy metabolism is one of the major functions of steroid hormones. This study was performed to explore whether testosterone can regulate the aerobic capacity of skeletal muscles via myoglobin expression. To study this, changes in testosterone level were quantified, and the level of myoglobin protein was analyzed using Western blot in mice subjected to 6 weeks of training (T) or testosterone administration (A). Both treatments significantly increased the plasma testosterone level when compared to the untrained (U) or control (C) group. Training induced a significant increase in the myoglobin content in gastrocnemius and plantaris muscles (287 and 83%, respectively). Testosterone administration increased myoglobin concentration in plantaris (183%) but not in gastrocnemius. In extensor digitorum longus muscle the protein content decreased slightly after exercise, but increased 78% after testosterone administration. In soleus and rectus femoris muscles the myoglobin content was unchanged after both treatments. The data show that testosterone and training have differential effects on the concentration of myoglobin in some, but not all muscles. This may have an influence on the aerobic capacity in mouse skeletal muscles. The data demonstrated that both testosterone administration and training induced an increase in plasma testosterone level. However, the effects of the treatments on the myoglobin concentration differ.     

Ligand binding properties of two kinds of reconstituted myoglobins with iron porphycene having propionates: effect of beta-pyrrolic position of two propionate side chains in porphycene framework

An iron porphycene containing two propionate side chains at the 12th and 17th beta-pyrrolic positions of the porphycene ring was synthesized and incorporated into sperm whale apomyoglobin in order to investigate the O(2) and CO binding properties of the reconstituted ferrous myoglobin. The protein showed a slower O(2) dissociation rate by 1/20, compared to the native myoglobin, whereas the CO dissociation rates were found to be almost the same. This tendency is similar to the result of a previous study on the reconstituted myoglobin with a porphycene having the propionates at the 13th and 16th beta-pyrrolic positions. However, the present myoglobin showed a faster O(2) dissociation than the previously studied myoglobin. This finding suggests that the position of the two propionates as well as the symmetry of the porphycene framework is an important factor for obtaining a stable oxygenated iron porphycene myoglobin.     

Studies on myoglobin from the finback whale (Balaenoptera physalus). Preparation, physicochemical and immunochemical characterization, differentiation from sperm-whale myoglobin, amino acid composition and end-terminal analyses

1. Crystalline myoglobin was isolated from the skeletal muscle of the finback whale and fractionated, in its cyanmet form, into nine components (I-IX) by chromatography on CM-cellulose. Also in the cyanmet form, it was resolved into six components by electrophoresis on starch gel. Correspondence between the electrophoretic and chromatographic components was determined, and interconversion between components revealed by chromatography and electrophoresis. 2. The chromatographic myoglobin components were homogeneous in the ultra-centrifuge. Molecular weights of certain components were determined by means of sedimentation equilibrium and by gel filtration on Sephadex G-100. Values from these two methods corresponded to the minimum molecular weight calculated from the iron content. 3. The spectral properties of the chromatographic components were investigated in the visible and the ultraviolet ranges. 4. The major components of finback-whale myoglobin and sperm-whale myoglobin showed almost identical spectral, electrophoretic and chromatographic behaviours, but had different infrared spectra. The infrared spectra of the corresponding apoproteins were almost identical. 5. Rabbit antisera to sperm-whale myoglobin component X cross-reacted with finback-whale myoglobin components V, VI and VII only about 30%. 6. The major chromatographic components of finback-whale myoglobin have identical amino acid compositions. The polypeptide chain contains 151 amino acid residues and its molecular weight is 17504. 7. The N-terminal end of the chain is: [Formula: see text] Amino acids released from myoglobin by the action of carboxypeptidase A at different intervals were determined.     

Reactive complexes in myoglobin and nitric oxide synthase

In this overview some of our crystallographic and spectroscopic studies on reactive complexes in myoglobin and nitric oxide synthase are summarised. Myoglobin and nitric oxide synthase are both haemoproteins with some similar reaction intermediates. For myoglobin we have studied different intermediates generated in the reaction with hydrogen peroxide by X-ray diffraction, single-crystal microspectrophotometry, electron paramagnetic resonance spectroscopy, Mössbauer spectroscopy, resonance Raman spectroscopy and quantum refinement. Several of these myoglobin states are quite susceptible to radiation-induced changes during crystallographic data collection, and we have observed a radiation-induced change of the ferric resting myoglobin to aqua ferrous myoglobin, of myoglobin compound II to a proposed intermediate H, and of myoglobin compound III to peroxy myoglobin. For the myoglobin compound II/ intermediate H we observe a single-bonded Fe^IV-O species, which is probably protonated. The long Fe-O bond seen in the crystal structure can be supported by the observation of a new ¹⁸O-sensitive resonance Raman mode at 687 cm⁻¹. For nitric oxide synthase we detected with cryobiochemical methods in electron paramagnetic resonance spectra the first biopterin radical serving as electron donor to the ferrous-oxy complex, and that biopterin serves as a proton donor as well, in addition we could observe formation of the Fe(NO) complex with a amino-pterin cofactor capable to form a reactive radical.     

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.