Alterations in rabbit kidney protein expression following lead exposure as analyzed by two-dimensional gel electrophoresis

It was recently reported that low blood lead levels impaired kidney function in men. To develop a set of molecular markers of renal lead exposure and effect, we investigated changes in renal protein expression while approximating occupational lead exposure at subchronic, low blood levels. Lead was administered to male Dutch Belted rabbits as a lead acetate solution adjusted weekly to achieve and maintain the target blood lead levels of 0, 20, 40, and 80 microg/dL for 15 weeks. Lead exposure did not affect kidney or body weights. The effect of increasing blood lead on protein expression was evaluated in rabbit kidney by large-scale two-dimensional electrophoresis (2-DE). Significant quantitative changes (p < 0.05) occurred in a dose-related manner in 12 proteins at 20 microg/dL exposure, 25 at 40 microg/dL, and 102 at 80 microg/dL. At a higher level of significance (p < 0.001), 40 microg/dL blood lead resulted in one protein alteration and 80 microg/dL affected 14 proteins. A set of quantitatively altered charge variants was tentatively identified as glutathione-S-transferase (GST), based on similar observations in rodents subjected to short-term, very high lead exposure. The significance of the protein alterations observed as markers of toxicity awaits their conclusive identification. Investigation of the kidney 2-DE profile in lead-exposed rabbit may be useful in understanding the mechanism of lead nephrotoxicity in humans.

Regional protein alterations in rat kidneys induced by lead exposure

Lead is a potent neuro- and nephrotoxin in humans and a renal carcinogen in rats. Previous studies have detected lead-induced increases in the activities of specific detoxification enzymes in distinct kidney cell types preceding irreversible renal damage. While preferential susceptibility of the highly vascularized cortex to the effects of lead is clear, lead effects on the medullary region have remained unexplored. The present study was undertaken to investigate the extent to which regional renal protein expression differs and to determine which, if any, regionally distinct protein markers indicative of lead's renotoxic mechanism might be detected in kidney cortical and medullary cytosols. We examined protein expression in these two functionally and anatomically distinct regions, and identified several proteins that are differentially expressed in those regions and were significantly altered by lead. Kidney cytosols from rats injected with lead acetate (114 mg/kg, three consecutive daily injections) were separated by two-dimensional electrophoresis. Lead exposure significantly (P<0.001) altered the abundance (either or) of 76 proteins in the cortex and only 13 in the medulla. Eleven of the proteins altered in the protein patterns were conclusively identified either by matrix-assisted laser desorption/ionization mass spectrometry/electrospray ionization-mass spectrometry (MALDI-MS/ESI-MS) analysis of peptide digests, immunological methods, or by gel matching. Several of the cortical proteins altered by lead were unchanged in the medulla while others underwent similar but lesser alterations. These observations reflect the complexity of lead's nephrotoxicity and endorse the application of proteomics in mechanistic studies as well as biomarker development in a variety of toxicologic paradigms.

Differential expression of cytosolic proteins in the rat kidney cortex and medulla: preliminary proteomics

The rodent kidney is a target of many xenobiotics and is typified by regionally specific structure and function. This renders distinct regions of the kidney differentially susceptible to toxic exposure and effect. To characterize these differences at the proteome level, protein patterns from male rat kidney cortex and medulla cytosols were examined by two-dimensional electrophoresis (2-DE) and image analysis and prominent proteins identified immunologically or by matrix-assisted laser desorption/ionization-mass spectrometry (MALDI-MS) and electrospray/ionization-tandem mass spectrometry (ESI-MS/MS) sequence tag identification. An average of 727 protein spots were resolved and matched to the cortex cytosol reference pattern, and 716 in the medulla. Of this total, 127 proteins were found to differ in abundance (86 higher in cortex; 41 higher in medulla) (P < 0.001). Of those proteins that were detectable in both cortex and medulla, the abundance of 97 differed significantly while 30 proteins were found to be unique to one region or the other (26 in cortex, 4 in medulla). Twenty protein spots were identified and their regional differences are discussed. These results both confirm and expand our understanding of the molecular heterogeneity characterizing structurally and functionally distinct regions of the kidney and serve as a useful foundation for future nephrotoxicologic studies.

Glutathione S-transferases: two-dimensional electrophoretic protein markers of lead exposure

Glutathione S-transferases (GST) are a family of detoxification isoenzymes that catalyze the conjugation of xenobiotics and their metabolites with reduced glutathione. Lead exposure in rats is known to induce GST isoenzymes in the liver and kidney. These changes in expression have potential use as biomarkers of lead exposure. Because two-dimensional electrophoresis (2-DE) enables one to analyze both protein abundance changes and chemical changes in protein structure, 2-DE was used to determine the effect of in vivo lead exposure on GST isoform expression in rat kidney cytosols. Male Sprague-Dawley rats were exposed to inorganic lead, and proteins were separated by conventional ISO-DALT and NEPHGE-DALT techniques and blotted for immunological identification. Lead exposure caused detectable inductions in both GSTP1 and GSTM1 and quantifiable charge modification in GSTP1. These preliminary data confirm the utility of 2-D electrophoretic GST analysis as indicative of lead exposure and toxicity and support its use for further elaboration of lead's effects on renal protein expression.

Two-dimensional electrophoresis of precision-cut testis slices: toxicologic application

Advances in tissue slice technology and a recent novel application of this technique to reproductive toxicology using bovine testis have demonstrated the remarkable utility of this approach. The objective of the present study was to combine this in vitro toxicity test system with large-scale two-dimensional polyacrylamide gel electrophoresis (2-DE) to detect and study alterations in testicular-slice protein patterns as molecular correlates of 1,3,5-trinitrobenzene (TNB) and 1,3-dinitrobenzene (DNB) toxicity. Previous studies have shown that testicular slices remain viable for > 24 h and, as measured by protein synthesis inhibition, TNB causes dose-related injury. Tissue-slices were prepared from bovine testicles incubated for 2, 4 or 6 h and exposed to either 100 microM, 500 microM or 1 mM DNB or TNB in the incubation medium. Slices were collected, solubilized, and separated by large scale 2-DE. Resulting protein patterns were then examined by image analysis, which revealed coefficients of variation in protein spot abundance comparable to patterns from fresh rodent tissue samples. Furthermore, specific protein alterations indicated dose-related inductions and declines in protein abundance, some progressive over time. The results of this investigation demonstrate the potential toxicologic utility of combining in vitro tissue-slice technology with high-resolution 2-DE protein mapping. The consolidation of these methods offers a novel approach for toxicity screening and testing, reduces experimental cost, and reduces the use of laboratory animals.

Two-dimensional electrophoretic analysis of compartment-specific hepatic protein charge modification induced by thioacetamide exposure in rats

Thioacetamide (TA) is a well-known hepatotoxicant. It has been reported that an obligate intermediate of TA binds to proteins with the formation of acetylimidolysine derivatives that are responsible for TA-induced hepatotoxic effects. TA has also been reported to cause chemically induced cell death via both apoptosis and necrosis. The objective of this study was 2-fold: first, to investigate the effect of TA exposure on protein charge modifications in the rat liver and second, to study the role of these molecular correlates in the regulation of cell death. Male Sprague-Dawley rats (200-225 g, 7-8 weeks old) were divided into four major groups and treated intraperitoneally with a 12-fold dose range of TA (50, 150, 300, and 600 mg TA/kg) dissolved in water. Using whole liver extracts, alterations in the hepatic protein pattern following treatment with the 12-fold dose range of TA were studied using high-resolution, two-dimensional polyacrylamide gel electrophoresis and computerized image analysis. The results indicate that charge modification was clearly evident as early as 2 hr with the lowest dose of 50 mg TA/kg. At this dose and time endoplasmic reticulum proteins, calreticulin, grp78, and ER6O exhibited acidic charge variants. The effect of TA became more prominent with dose and time. Generally the elevation of charge modification indices (CMI) by TA appeared to reach a peak between 4 and 6 hr and then while CMI either leveled off or declined in the lower two doses of 50 and 150 mg TA/kg, it continued to remain elevated with the higher doses of 300 and 600 mg TA/kg. This dichotomy in the elevation of CMI is in close correspondence to the pattern of cell death observed with a similar dose range of TA, where lower doses (50 and 150 mg TA/kg) predominantly cause cell death via apoptosis while higher doses cause cell death via necrosis. Delayed charge modification was observed with the cytosolic hsc70s with the 300 and 600 mg TA/kg treatments, indicating that the reactive metabolite(s) slowly leak out into the cytosol from the endoplasmic reticulum. There were no alterations in the mitochondrial proteins hsp60 and grp75, suggesting that TA has no effect on the mitochondrion, its effects primarily being confined to the endoplasmic reticulum. The concept of looking at these proteins as biomarkers of tissue injury has validity. These changes may be indicators of bioactivation and adduct formation and also may be signaling events in the regulation of the mode of cell death.

Toxicant-induced alterations in two-dimensional electrophoretic patterns of hepatic and renal stress proteins

Recent studies in this laboratory and by others suggest that two-dimensional polyacrylamide gel electrophoresis of proteins (2-DE) possesses significant utility in the detection of chemical toxicity and in providing information regarding toxic mechanism. After having identified a set of specific heat-shock and glucose-regulated proteins whose expression in rodent liver and kidney is highly conserved and constitutive, we compared the effect of in vivo exposure to perfluoro-n-octanoic acid and perfluoro-n-decanoic acid on their expression. The following stress proteins were identified, their x, y coordinate positions mapped, and abundance statistically analyzed and compared: hsp32, hsp60, hsc70, hsp70, hsp90, grp75, grp94, protein disulfide isomerase (PDI), and ER60. We report here that the stress response to perfluorocarboxylic acids is tissue-, toxicant-, and stress protein class-specific and dose-related. Furthermore, because nearly all of the proteins studied were constitutively expressed at detectable levels in both liver and kidney, the 2-DE stress protein pattern may be suitable to future toxicologic screening applications.

A23187 releases bound rather than free calcium from calcium-loaded liposomes

We have investigated sonication-, osmotic shock-, and A23187-induced calcium and horseradish peroxidase release from phosphatidylcholine liposomes. We report that sonication and osmotic shock both cause release of liposome-entrapped horseradish peroxidase activity, thus, completely releasing the entrapped volume into and mixing it with the external medium. However, we find that neither sonication nor osmotic shock releases significant amounts of calcium from liposomes pre-loaded with calcium, while A23187 causes release of significant amounts of calcium from similarly prepared liposomes. We also find that A23187 can release calcium from liposomes after release of entrapment volume by sonication or osmotic shock. Alteration of the net charge of liposomes by substitution of phosphatidylcholine with phosphatidylserine or stearylamine dramatically changes the amount of calcium associated with calcium-loaded liposomes; sonication or addition of A23187 to liposomes containing significant amounts of PS does not appear to release calcium bound to these vesicles. These results suggest that a large fraction (> 99%) of the calcium associated with liposomes is bound to the membranes of the liposomes and that the calcium released by A23187 is due to release of bound rather than entrapped calcium.

Modification of hepatic immunoglobulin heavy chain binding protein (BiP/Grp78) following exposure to structurally diverse peroxisome proliferators

This investigation was conducted to determine the comparative effect of structurally diverse peroxisome proliferators (PP) on the two-dimensional protein pattern of rat liver whole homogenates. Perfluoro-n-decanoic acid (PFDA), perfluoro-n-octanoic acid (PFOA), clofibrate, and di(2-ethylhexyl)phthalate (DEHP) are all known to cause the proliferation of hepatic peroxisomes and the induction of peroxisomal beta-oxidative and microsomal omega-oxidative enzymes. To clarify the mechanistic differences between these compounds with regard to the liver, we examined the unique patterns of protein alteration produced by in vivo exposure to them. Following exposure to various doses, whole liver homogenates were prepared and separated by two-dimensional gel electrophoresis (2DE) using the ISO-DALT system. Stained gels were digitized and protein patterns analyzed using the Kepler 2D gel analysis system. Immunoglobulin heavy chain binding protein (BiP), also known as 78-kDa glucose-regulated protein (Grp78), was identified immunologically and by comigration of recombinant Grp78. BiP is a luminal endoplasmic reticular protein that functions in the assembly and folding of nascent proteins as they enter the ER. The present results suggest a selective posttranslational modification of BiP following PFDA exposure. Single-dose exposure to PFDA was associated with a notable charge modification of BiP that persists up to 30 days. PFOA, clofibrate, and DEHP had less effect in this regard. The identity of BiP/Grp78 as the halothane hepatitis-associated trifluoroacetylated protein was also demonstrated. The nature of this PFDA-associated protein modification (reactive metabolite conjugation, abnormal ribosylation, or phosphorylation) is currently under investigation.(ABSTRACT TRUNCATED AT 250 WORDS)

Induction of enoyl-CoA hydratase by LD50 exposure to perfluorocarboxylic acids detected by two-dimensional electrophoresis

The effect of in vivo exposure to perfluoro-n-octanoic and perfluoro-n-decanoic acids was examined in the rat liver by two-dimensional electrophoresis (2DE). Using nonequilibrium pH-gradient electrophoresis in the first dimension separation, proteins associated with the mitochondrial/peroxisomal cell fraction were observed and immunologically identified. Conspicuous inductions in peroxisomal enoyl-CoA hydratase and other proteins of the peroxisomal beta-oxidative pathway were observed following single-dose exposure to each compound. The abundance of the tentatively-identified mitochondrial equivalent, crotonase, was not altered by these intoxications. These results confirm previous observations of perfluorocarboxylic acid toxicity and support the use of 2D protein-pattern alterations in biomarker research. The ability to identify this type of alteration via 2DE, in association with specific toxic effects by chemically related compounds, may provide new and additional markers for chemical-induced tissue damage.

Hepatic protein pattern alterations following perfluorodecanoic acid exposure in rats

The effect after 8 days of 20 and 50 mg/kg in vivo exposure to perfluoro-n-decanoic acid (PFDA) on the protein pattern of rat liver whole homogenates was studied using high-resolution, large-scale two-dimensional polyacrylamide gel electrophoresis. PFDA exposure altered 13 proteins reproducibly in each of 5 samples tested. While most of the altered proteins remained unidentified, several known mitochondrial proteins were induced by PFDA as were others in a dose-related manner. Conversely, PFDA caused the reduction of albumin as well as several unknown proteins, also in a dose-related manner. Cytoskeletal proteins were unaffected by PFDA. The present results suggest that PFDA's toxic mechanism may involve more than membrane integration and lipid accumulation. Changes in the two-dimensional protein pattern indicate that selective protein synthetic or catabolic processes may undergo qualitative alterations after PFDA treatment as well.

Soleus muscle atrophy in rats induced by cast immobilization: lack of effect by anabolic steroids

To test the hypothesis that an anabolic steroid such as nandrolone decanoate (ND) will ameliorate or abolish disuse-mediated alterations resulting from five weeks of hindlimb immobilization, female Sprague-Dawley rats were divided into six groups: control, control + ND, shortened-immobilized, shortened-immobilized + ND, stretched-immobilized, and stretched-immobilized + ND. Immobilization was accomplished by wrapping hindlimbs with plaster of Paris. Nandrolone decanoate in sesame oil was administered via weekly intraperitoneal injection (7 mg/kg) while nontreated rats received equivalent volumes of the vehicle. After five weeks selected morphometric, biochemical, and mechanical parameters were examined in the slow-twitch soleus muscle (SOL). Muscle wet weight fell from a control value of 145 +/- 19 mg to 70 +/- 8 mg (p less than .05) in the immobilized-shortened group where ND had no effect (81 +/- 11 mg). Muscle stretch alone prevented weight loss (159 +/- 31 mg). The addition of ND resulted in significant SOL hypertrophy (200 +/- 42 mg), p less than .05. Immobilization resulted in a significant shift in muscle protein distribution toward sarcoplasmic protein, a change unaltered by ND but abolished by stretch. Muscle strength, as indicated by peak tetanic tension, fell 45% (p less than .05) as a result of shortened immobilization. Nandrolone decanoate had no effect on this condition, although the ameliorating effect of stretch was abolished when in combination with ND treatment. The elevation observed in maximal shortening velocity (shortened-immobilized) was unaffected by ND alone, but abolished by stretch with or without ND treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of ageing and exercise on skeletal muscle function

The contractile and selected biochemical properties of fast- and slow-twitch skeletal muscle were studied at 9, 18, and 28 months of age in sedentary and regularly exercised rats. The isometric twitch duration was prolonged with aging in both the fast- and slow-twitch muscle. This effect was primarily due to a prolonged one-half relaxation time (1/2RT), which developed late in life. Regular exercise tended to further prolong the twitch duration, particularly in the slow-twitch soleus. Surprisingly, twitch and tetanic tension (Po), peak rate of tension development and decline, and the maximal shortening velocity were all unaltered between 9 and 28 months of age. Furthermore, regular exercise (running or swimming) had little or no effect on these properties. The prolonged 1/2RT with aging could not be explained by a decreased rate of Ca2+ sequestration by the sarcoplasmic reticulum, as the rate of Ca2+ uptake measured in muscle homogenates was unaltered in any of the muscles studied between 9 and 28 months. The degree of muscle fatigue (decline in Po) with 30 min of contractile activity in the slow-twitch soleus was not affected by aging. However, lactate reached two-fold higher levels and glycogen fell to considerably lower levels in the muscles of the old rats. This suggests an increased glycolysis and glycogen utilization during contractile activity in aged rats.

Effect of hindlimb immobilization on the fatigability of skeletal muscle

The soleus (SOL) and extensor digitorum longus (EDL) muscles of the rat were studied in situ (33.5 degrees C) after 6 wk of disuse atrophy produced by hindlimb immobilization (IM). IM resulted in depressed peak twitch (Pt) and tetanic (Po) tension as well as a decreased rate of tension development (+dP/dt) and decline (-dP/dt) in the slow-twitch SOL. The fast-twitch EDL was affected to a lesser extent, because only Po (g . cm-2) and Po,-dP/dt (g . cm-2 . ms-1) were depressed after IM. Twitch duration, as measured by contraction time and one-half relaxation time, was shortened in the SOL and prolonged in the EDL. In both the fast and slow muscles 30 min of electrical stimulation resulted in a significant decline in Po. Relative to the prefatigued Po, the atrophied and control muscles showed a similar fatigue pattern. This occurred in spite of lower ATP and glycogen concentrations and higher lactate levels in the atrophied muscles. Our results indicate significant impairment of contractile function following IM in fast and slow muscles with preferential alterations in the slow SOL. In addition, despite a lower resting capacity and an increased dependence on glycolysis, contractile properties of atrophied muscles differed little from control muscles in their pattern of response to 30 min of electrical stimulation.

Acid phosphatase and protease activities in immobilized rat skeletal muscles

The effect of hind-limb immobilization on selected lysosomal enzyme activities was studied in rat hind-limb muscles composed primarily of type I, IIA, or IIB fibers. Following immobilization, acid protease and acid phosphatase both exhibited significant (P less than 0.05) increases in their activity per unit weight in all three fiber types. Acid phosphatase activity increased at day 14 of immobilization in the three muscles and returned to control levels by day 21. Acid protease activity also changed biphasically, displaying a higher and earlier rise than acid phosphatase. The pattern of change in acid protease, but not acid phosphatase, closely parallels observed muscle wasting. The present data therefore demonstrate enhanced proteolytic capacity of all three fiber types early during muscular atrophy. In addition, the data suggest a dependence of basal hydrolytic and proteolytic activities and their adaptive response to immobilization on muscle fiber composition.

Effect of thyrotoxicosis on sarcoplasmic reticulum in rat skeletal muscle

The effect of thyrotoxicosis on the capacity of fragmented sarcoplasmic reticulum (FSR) and crude homogenate (CH) to sequester Ca2+ was determined in rat muscle for the slow-twitch type I soleus (SOL), the fast-twitch type IIA deep region of the vastus lateralis (DVL),and the fast-twitch type IIB superficial region of the vastus lateralis (SVL). The maximal rate of Ca2+ uptake (Vmax) and Km were determined in both the CH and FSR preparations, and the total Ca2+ uptake capacity of the CH was determined. In the slow SOL, thyrotoxicosis increased the Vmax (8.20 +/- 0.96 vs. 15.70 +/- 0.92 mumol Ca2+ . g wet muscle-1 . min-1) and the total Ca2+ uptake (17.62 +/- 1.30 vs. 27.13 +/- 2.16 mumol Ca2+ . g wet muscle-1) of the CH preparation. Thyrotoxicosis increased the FSR yield 2.3-fold in the slow-twitch SOL; however, the kinetic characteristics (Vmax and Km) of these vesicles were not altered. Thyrotoxicosis had no effect on the CH and FSR preparations in either the type IIA or type IIB sample. These results can be explained by a thyroid hormone-mediated increase in the quantity of the sarcoplasmic reticulum in type I muscle and suggest no effect on the hormone on the qualitative nature of the Ca2+-enzyme interaction.

Effect of disuse on sarcoplasmic reticulum in fast and slow skeletal muscle

The effect of 6 wk of hindlimb immobilization on rat skeletal muscle sarcoplasmic reticulum (SR) was determined in the slow-twitch, type I soleus (SOL), the fast-twitch, type IIA deep region of the vastus lateralis (DVL), and the fast-twitch, type IIB superficial region of the vastus lateralis (SVL). Immobilization produced a significant decline in the Ca2+ uptake rate (Vmax) of SR vesicles from the slow SOL (0.930 +/- 0.116 to 0.365 +/- 0.071 mumol Ca2+ . mg-1 . min-1), while the SR Vmax increased in the fast SVL (2.763 +/- 0.133 to 5.209 +/- 0.687) and was unaltered in the DVL. Vesicles from the fast SVL and DVL also exhibited a higher total Ca2+ uptake capacity following immobilization. An evaluation of the time course of the immobilization-mediated effect revealed an increased Ca2+ uptake capacity in all three samples after 1 wk. In the SOL total Ca2+ uptake returned to control level after 2 wk, while in the fast-twitch muscles the higher capacities were maintained. The Ca2+-stimulated SR ATPase activity was not altered in any of the muscles studies, although the total SR ATPase activity increased twofold in the slow SOL.

Hindlimb immobilization: length-tension and contractile properties of skeletal muscle

The effect of hindlimb immobilization (IM) on the contractile properties of fast and slow skeletal muscle was studied in rats following various periods of IM ranging from 1 to 42 days; muscle atrophy, muscle, fiber, and sarcomere length, and the length-tension characteristics were determined after 42 days of IM. The slow-twitch soleus (SOL), the fast-twitch extensor digitorum longus (EDL), and the fast-twitch superficial region of the vastus lateralis (SVL) all showed rapid atrophy following the onset of IM, reaching a new reduced steady-state weight by day 21. After 42 days of IM the passive tension (g) and active twitch tension (g/cm2) plotted vs. muscle length (cm) were shifted to the left for the slow-twitch SOL, indicating a decreased extensibility compared with control muscles. The peak tetanic tension of the slow SOL declined to 47% of the control level of 2,893 +/- 125 g/cm2, whereas the fast EDL maintained 72% of its initial force of 4,392 +/- 229 g/cm2, and the fast SVL was unaltered by IM. Peak twitch tension and peak rate of tension development and decline fell rapidly in the slow SOL while remaining relatively unaltered in the fast-twitch muscles. Surprisingly, maximal isotonic shortening velocity was elevated in both fast and slow muscles with IM. These results indicate that IM produces muscle atrophy in fast as well as slow skeletal muscle and, in addition, causes fiber type-specific changes in the contractile properties.

Recovery time course in contractile function of fast and slow skeletal muscle after hindlimb immobilization

Contractile properties were evaluated in rats remobilized after 6 wk of hindlimb casting to evaluate the regenerative capacity of fast and slow skeletal muscles. Contractile parameters were determined in vitro (22 degrees C) in the type I soleus (SOL), type IIA and IIB extensor digitorum longus (EDL), and the type IIB superficial vastus lateralis (SVL). Immobilization (IM) shortened the SOL isometric twitch duration after which contraction time and half-relaxation time required 4 and 7 days to recover, respectively. In contrast, IM prolonged the twitch in the EDL and SVL and recovery required 14 and 7 days, respectively. Peak tetanic tension (g/cm2) fell in the SOL and EDL with IM and full recovery required 28 days. In this regard, the SVL remained unaltered. Rates of tension development and decline remained essentially unaltered in the fast muscles after IM but fell in the SOL, requiring 14 days to fully recover. Maximal shortening velocity, which had been elevated in all three muscles by IM, recovered rapidly. The present results demonstrate that both fast and slow muscle have the ability to completely recover from 6 weeks of IM.

Muscle fatigue with prolonged exercise: contractile and biochemical alterations

Alterations in the contractile and biochemical properties of fast and slow skeletal muscle were studied in rats following a prolonged swim to exhaustion. The exercise produced glycogen depletion (less than 1 mg/g tissue) in muscles representative of all three fiber types; the isometric contractile properties were altered in the 84% type I soleus (SOL) and the 60% type IIa extensor digitorium longus (EDL) but not in the 100% type IIb superficial region of the vastus lateralis (SVL). Peak tetanic tension (Po) and the rate of tension development and decline all decreased after prolonged exercise in both the SOL and the EDL. The maximal isotonic shortening velocity was highly correlated with the myofibrillar ATPase activity, and both were relatively resistant to fatigue. Furthermore, the Ca2+ sensitivity of the myofibrils was unaffected by exercise in both fast and slow muscle. The Ca2+ uptake capacity of the sarcoplasmic reticulum (SR) was reduced in both the SOL and the fast-twitch type IIa deep region of the vastus lateralis, whereas the SR ATPase activity was unchanged. Our findings provide evidence that prolonged exercise produces alterations in contractile and biochemical properties of type I and IIa but not type IIb fibers and that muscle fatigue as measured by a decline in Po is not necessarily correlated with glycogen depletion.

Lipid metabolism in skeletal muscle of endurance-trained males and females

Bipsies were obtained from the gastrocnemius muscle of 13 male and 12 female distance runners and analyzed for [14C]palmitoyl-CoA oxidation, fiber composition, and the activities of selected enzymes. The male and female runners were similar in terms of maximal oxygen uptake (VO2max), training mileage, fiber compositions, and data collected during a 60-min treadmill run at 70% VO2max. Muscle succinate dehydrogenase and carnitine palmitoyl transferase activities were, however, significantly greater (P less than 0.05) in the male than in female runners. In addition, the male runners' muscle also showed a greater capacity to oxidize palmitoyl CoA. Little relationship, however, was found between muscle lipid metabolism, enzyme activities, and the calculated (respiratory exchange) fraction of energy derived from fat during 60 min of running at 70% VO2max. Although these data support the concept that endurance training (80-115 km/wk) markedly enhances the capacity of muscles to metabolize fats, the factors that regulate the usage of lipids during prolonged exercise do not appear to be limited by the capacity of the fibers to oxidize fatty acids, as determined by in vitro measurements.

Adaptations in skeletal muscle following strength training

Five men were studied before and after 7 wk of isokinetic strength training to determine its effects on muscle enzyme activities and fiber composition. One of the subject's legs was trained using 10 repeated 6-s maximal work bouts, while the other leg performed repeated 30-s maximal knee extension exercise. The total work accomplished by each leg was constant. Training 4 times/wk achieved similar gains in peak torque for both legs at the training velocity (3.14 rad/s) and at slower speeds. Fatigability of the knee extensor muscles, as measured by a 60-s exercise test, was similar in both legs after training. Biopsy specimens showed significant changes in the % of the muscle area composed of type I and IIa fibers as a result of both strength training programs. In terms of muscle enzymes, only the 30 s exercise program resulted in elevated glycolytic, ATP-CP and mitochondrial activities. Despite these changes, none of the parameters measured were found to be related to the gains in either muscle strength or fatigability during maximal isokinetic contractions.