Julie M. Fagan

Quantitation of oxidative damage to tissue proteins

Active oxygen species are thought to be involved in many physiological and pathological processes and are known to oxidatively modify DNA, lipids and proteins. One such modification is the addition of carbonyl groups to amino acid residues in proteins. The number of carbonyl groups on proteins can be quantitated spectrophotometrically using 2,4-dinitrophenylhydrazine (DNPH). The DNPH assay described in the literature was found to be unreliable in samples containing high amounts of chromophore (e.g. hemoglobin, myoglobin, retinoids). By using an HCl-acetone wash, hemes from the chromophores could be extracted, enabling the determination of carbonyl content to be made even in highly colored tissue extracts. Residual DNPH, which was also found to interfere with the assay, was removed by additional washes with trichloroacetic acid and ethanol-ethylacetate. These improvements are known to remove lipids, do not lengthen the time required to do the assay, permit quantification of carbonyl content in 1-4 mg protein from a variety of tissue types and provide a sensitive and reliable method for assessing oxidative damage to tissue proteins.

Response to trauma of protein, amino acid, and carbohydrate metabolism in injured and uninjured rat skeletal muscles☆

Soft tissue injury to one hindlimb produced trauma in rats without affecting their food intake or weight gain. Histologic examination showed damage to the soleus and gastrocnemius muscles but not to the extensor digitorum longus muscle. The protein content of the injured soleus muscle was lower than that of the contralateral soleus at one day after injury, and was reflected in vitro by a faster rate of protein degradation. The injured soleus also showed greater rates of protein synthesis, glucose uptake, glycolysis, oxidation of glucose, pyruvate, and leucine, and de novo synthesis of alanine. During three days after the injury, urinary nitrogen excretion increased progressively and was paralleled by a faster rate of protein degradation in uninjured muscles incubated with glucose, insulin, and amino acids. In these muscles, the inhibition of protein degradation by insulin diminished, while its stimulation of protein synthesis was unaffected. This insensitivity of proteolysis to insulin in trauma can explain the increased rate of this process. The oxidation of glucose and pyruvate were lower in the diaphragms of traumatized than of normal rats incubated with leucine, while glycolysis and uptake of 2-deoxyglucose did not differ. The degradation of leucine and isoleucine was greater in the diaphragms of traumatized animals and was associated with a faster de novo synthesis of alanine. For the uninjured soleus muscles of the traumatized rats, the slower rates of oxidation of glucose, glycolysis, and uptake of 2-deoxyglucose in the presence of insulin showed an insensitivity of glucose metabolism to this hormone. In contrast, no differences were seen in these various metabolic processes between the extensor digitorum longus muscles of traumatized and normal rats. These data suggest that the response of skeletal muscles to trauma may depend on their physiologic and biochemical characteristics.

Relationship of the reduction-oxidation state to protein degradation in skeletal and atrial muscle.

Abstract Changes in proteolysis were correlated with the cell reduction-oxidation state in rat diaphragm and atrium. Protein degradation was measured in the presence of cycloheximide as the linear release of tyrosine into the medium. Intracellular ratios of lactate/pyruvate, total NADH NAD , and malate/pyruvate were used as indicators of the muscle reduction-oxidation state. Incubation of diaphragms with leucine (0.5–2.0 m m ) or its transamination product, sodium α-ketoisocaproate (0.5 m m ), resulted in a lower rate of proteolysis and a higher ratio of lactate/pyruvate and NADH NAD . These effects of leucine could be abolished by inhibiting its transamination with l -cycloserine. Unlike leucine, neither isoleucine nor valine alone produced any change in these parameters. Incubation of diaphragms with glucose (20 m m ) or atria with sodium lactate (2 m m ) produced a diminution of tyrosine release from the muscles and a rise in the ratio of total NADH NAD . Similarly, in incubated diaphragms of fasted rats, the anabolic effects of insulin, epinephrine and isoproterenol on protein degradation were associated with a higher malate/pyruvate ratio. In catabolic states, such as fasting, cortisol treatment of fasted, adrenalectomized rats or traumatization, enhanced muscle proteolysis was observed. Fresh-frozen diaphragms from these rats had both lower lactate/pyruvate and malate/pyruvate ratios than did muscles from control animals. These data show that diminution of proteolysis in diaphragm is accompanied by an increase of the NAD(P)H NAD(P) ratios. In contrast to these findings, chymostatin and leupeptin, which inhibit directly muscle proteinases, caused a decrease of the lactate/pyruvate and malate/pyruvate ratios. These results suggest that protein degradation in diaphragm and atrium is linked to the cellular redox state.

Effect of Beta Agonists on Protein Turnover in Isolated Chick Skeletal and Atrial Muscle

Various 6-adrenergic agonists were found to inhibit rates of protein degradation and net protein breakdown in isolated chick extensor digitorum communis (EDC) and atrial muscles. Rates of protein synthesis were not altered by these compounds. The 3-agonist cimaterol inhibited rates of protein degradation in EDC muscles incubated with or without amino acids and insulin. Cimaterol also inhibited the increased proteolysis induced by injury to muscle or by incubating muscles at body temperature (42°C) versus 37CC. Thus, 3-agonists may help promote skeletal muscle accretion in vivo even under conditions of severe negative nitrogen balance by slowing muscle proteolysis.

Rat muscle protein turnover and redox state in progressive diabetes.

Protein synthesis and degradation, and redox state were measured in soleus and extensor digitorum longus muscles of rats up to 12 days after injection of streptozotocin. Muscle growth was slower in these animals apparently due to slower protein synthesis throughout the duration of diabetes. Up to day 4 after injection of streptozotocin or withdrawal of insulin from treated, diabetic animals, the muscle ratio of lactate/pyruvate, an indicator of the cytoplasmic NAD+ redox couple, was lower and protein degradation was faster than in control muscles. Thereafter, the ratio of lactate/pyruvate was greater and protein degradation was slower than in size- or age-matched control muscles. Insulin treatment in vitro or in vivo increased lactate/pyruvate and decreased proteolysis. Therefore, in muscles of streptozotocin-diabetic rats, the initial increase and later fall in proteolysis, and the inhibition of proteolysis by insulin, may correlate with opposite changes in NADH/NAD+.

Comparison of the multicatalytic proteinases isolated from the nucleus and cytoplasm of chicken red blood cells

1. Two chromatographically distinct multicatalytic proteinases (MCPs) were isolated from the cytoplasm of chicken red blood cells and one MCP was purified from the nuclei. 2. The nuclear and the majority (97-99%) of the cytoplasmic multicatalytic proteolytic activity were chromatographically similar and differed from the minor cytoplasmic activity in their elution from hydroxylapatite, number of subunits on 2D-SDS-PAGE, and in their sensitivity to proteinase inhibitors. 3. Dichloroisocoumarin, a serine proteinase inhibitor, inhibited the hydrolysis of fluorogenic peptides but stimulated the degradation of casein by the multicatalytic proteinases suggesting that this enzyme has distinct active sites for protein and peptide hydrolysis.

Effects of oxygen deprivation on incubated rat soleus muscle

Isolated soleus muscle deprived of oxygen produces more lactate and alanine than oxygen-supplied muscle. Oxygenated muscle synthesized glutamine, while anoxic muscle used this amino acid. Oxygen deprivation decreased adenine nucleotides leading to the efflux of nucleosides. Protein synthesis and degradation responded differently to anoxia. Synthesis almost completely ceased, while proteolysis increased. Therefore, protein degradation in soleus muscle is enhanced when energy supplies and oxygen tension are low.

Polyamines inhibit the ATP-dependent proteolytic pathway in rabbit reticulocyte lysates

Reticulocytes contain a soluble nonlysosomal proteolytic pathway that requires ATP and ubiquitin. Polyamines at physiological concentrations were found to inhibit rapidly the ATP‐dependent proteolytic system in reticulocyte lysates; spermidine and putrescine inhibited this process by 26–72% and spermine by 71–96%. Spermine had little effect on the ATP‐independent breakdown of oxidant‐treated hemoglobin. By fractionating the ATP‐dependent system, we show that polyamines inhibit the ATP‐dependent degradation of ubiquitin‐protein conjugates.

Identification of a soluble enzyme from C3H/10T12 cells which is inhibited by the Bowman-Birk proteinase inhibitor

The anticarcinogenic Bowman-Birk proteinase inhibitor (BBI) inhibits a 70-kDa serine proteinase in C3H/10T1/2 transformed fibroblasts. Two serine proteinases, the proline endopeptidase and a novel neutral proteolytic activity, both having a mass of approximately 70-kDa, were isolated from the cytoplasm of C3H/10T1/2 cells. BBI did not inhibit diisopropylfluorophosphate binding to the proline endopeptidase or its ability to hydrolyze peptides. However, BBI blocked the binding of diisopropylfluorophosphate and inhibited the cleavage of peptides by the novel cytoplasmic enzyme. Thus BBI does not inhibit the proline endopeptidase but another soluble 70-kDa serine proteinase from C3H/10T1/2 cells.

Rapid method for preparation of pure veratryl alcohol for the assay of lignin peroxidase

We present a simple method for the rapid preparation of veratryl alcohol by reducing commercially available veratraldehyde with sodium borohydride resulting in high-purity veratryl alcohol. The lag period in the activity of lignin peroxidase from Phanerochaete chrysosporium that is associated with use of commercial preparations of the substrate is eliminated with the use of pure veratryl alcohol. The compound affords also estimation of low enzymatic activity.