Abnormal Myocardial Contractility After Pediatric Heart Transplantation by Cardiac MRI

Cardiolog

Seasonal change and prolonged anoxia affect the kinetic properties of phosphofructokinase and pyruvate kinase in oysters

The effects of seasonal change, November versus July, and prolonged anoxia (96 h under N2 gas) on the properties of phosphofructokinase and pyruvate kinase from five tissues (gill, mantle, hepatopancreas, phasic adductor, catch adductor) of the oyster, Crassostrea virginica, were investigated. Both enzymes showed tissue-specific and season-specific changes in kinetic properties; for pyruvate kinase this correlated with seasonal differences in enzyme elution patterns on hydroxylapatite chromatography. Kinetic properties of both enzymes in winter were consistent with primarily catabolic roles in glycolysis with responsiveness to cellular energy demands, whereas in summer these enzymes may be more closely regulated with respect to the biosynthetic and gluconeogenic functions of the tissues. Anoxia-induced changes in phosphofructokinase properties were relatively minor but anoxia stimulated changes in pyruvate kinase properties and elution profiles on hydroxylapatite in all tissues except mantle, with much greater effects seen for the enzyme from winter versus summer animals. For example, anoxia-induced changes in pyruvate kinase from winter gill included a fourfold rise in the substrate affinity constant for phosphoenolpyruvate, a sevenfold increase in the concentration of fructose-1,6-bisphosphate needed to activate the enzyme by 50%, and a 50% decrease in the concentration of L-alanine that inhibits activity by 50%. Changes in pyruvate kinase kinetics and hydroxylapatite elution patterns during prolonged anoxia are consistent with covalent modification of pyruvate kinase but contrary to results for many other mollusc species, anoxia exposure appears to induce a dephosphorylation of the enzyme

Discordant responses of mitogen-activated protein kinases to anoxia and freezing exposures in hatchling turtles

The role of two vertebrate mitogen-activated protein kinases (MAPKs) in mediating responses to in vivo anoxia or freezing exposures was examined in four organs (liver, heart, kidney and brain) of hatchling red-eared turtles, Trachemys scripta elegans, which are naturally tolerant of these stresses. The extracellular signal-regulated kinases were not stress-activated except in brain of frozen turtles. The c-Jun NH2-terminal kinases (JNKs) were transiently activated by anoxia exposure in all four organs (after 1 h in brain or 5 h in other organs) but activity was suppressed during freezing except in brain which showed a transient activation of JNK after 1 h. Changes in the concentrations of the transcription factors, c-Fos and c-Myc, were also stress-and organ-specific. The patterns of MAPK activation in a stress-tolerant animal suggest the relative importance of these kinase pathways in cellular adaptation to oxygen deprivation or freezing and identify novel natural activators of MAPKs in vivo. The specificity of the signaling pathways is also emphasized here as the general whole-body stresses, anoxia and freezing, activated individual MAPKs in a tissue-, time-, and stress-dependent manner

Effects of seasonal change and prolonged anoxia on metabolic enzymes of Littorina littorea

The effects of seasonal change (July versus November) and prolonged anoxia (N2 atmosphere at 5 or 10°C for 6 days) exposure in vivo on the activities of 18 enzymes, as well as the kinetic properties of phosphofructokinase (PFK) and pyruvate kinase (PK), were investigated in foot muscle and digestive gland of the marine periwinkle Littorina littorea L. Seasonal differences in enzyme maximal activities were tissue-specific, with generally increased activities during the summer and changes in a greater number of enzymes in digestive gland than in foot muscle. Seasonal differences in the kinetic properties of PFK and PK were observed in both tissues. PK from digestive gland of winter animals showed a much higher S0.5 for phosphoenolpyruvate and stronger changes in enzyme kinetic properties in response to anoxia than did the enzyme in summer animals; this may suggest the presence of seasonal isozymes. The effects of anoxia were tissue- and season-specific. Anoxia exposure during the winter induced a greater number of changes in enzyme maximal activities in foot muscle than in digestive gland. Anoxia-induced changes in the kinetic properties of both PFK and PK were also seen in both organs. For PK, these changes were consistent with less active enzyme forms in the anoxic state. Hence, both seasonal and environmental (anoxia) factors influence enzyme maximal activities and kinetic properties in L. littorea

Activation of mitogen-activated protein kinases during natural freezing and thawing in the wood frog

The responses of mitogen-activated protein kinase (MAPK) family members, including ERK (extracellular signal-regulated kinase), JNK (c-Jun NH2- terminal kinase), and p38, in the metabolic responses to whole animal freezing (up to 24 h frozen at -2.5°C) and thawing (up to 4 h at 5°C after a 12 h freeze) were examined in four organs (liver, kidney, heart, brain) of the freeze-tolerant wood frog Rana sylvatica. Levels of the active phosphorylated form of p38 increased within 20 min as an early response to freezing in liver and kidney but rose later (after 12 h) in heart. Both JNK and p38 were activated during thawing in liver, kidney and heart with temporally-distinct patterns in each organ. The only MAPK response to freeze/thaw in frog brain was a transient elevation of p38 after 90 min thawing. ERK activity did not respond to freeze/thaw in any organ. The levels of c-Fos increased during freezing in kidney and brain whereas c-Jun was unaffected by freeze/thaw. Organ-specific responses by MAPKs, particularly p38, suggest that these may have roles in regulating metabolic or gene expression responses that may be adaptive in dealing with freezing stress or metabolic recovery during thawing

The effect of prolonged anoxia on enzyme activities in oysters (Crassostrea virginica) at different seasons

The effect of prolonged anoxia (96 h under a N2 atmosphere) during either winter (November) or summer (July) was investigated by measuring the maximal activities of 20 metabolic enzymes in gill, mantle, hepatopancreas, and phasic and catch adductor muscles of the oyster, Crassostrea virginica. The enzymes analyzed are involved in carbohydrate and amino acid metabolism, the pentose phosphate shunt, anaplerotic reactions of the TCA cycle, and phosphagen/adenylate metabolism. The data demonstrate that oyster metabolism is influenced by both long-term seasonal change and by shorter-term environmental insult (anoxia). Seasonal changes were concentrated among enzymes involved in glycogen metabolism whereas the prominent response to anoxia was suppression of PK activity. Anoxia exposure induced tissue- specific changes in enzyme activities suggesting a substantial metabolic reorganization involving both coarse controls on enzyme amount and reversible covalent modification. In addition, the effects of anoxia on enzymes of intermediary metabolism were seasonally dependent and more widespread in the winter. These results demonstrate the interaction of two environmental variables (season, anoxia) and suggest the importance of season as a modifying factor in the anoxic response

Mitogen-activated protein kinases and anoxia tolerance in turtles

The response of two vertebrate mitogen-activated protein kinase (MAPK) family members, the extracellular signal-regulated kinases (ERKs) and c-Jun NH2-terminal kinases (JNKs), to anoxia exposure in vivo was examined in organs (liver, heart, kidney, brain, spleen) of the anoxia-tolerant adult turtle, Trachemys scripta elegans. ERKs activities rose during anoxia only in spleen (a 2.8-fold increase). JNK activity showed a significant increase only in liver (4-fold increase) after 5 hr of anoxic submergence but declined thereafter. Levels of the transcription factor c-Fos were strongly suppressed in liver, heart, and kidney of anoxia-exposed turtles, whereas levels increased 2-fold in anoxic brain. The effect of anoxia on c-Myc was organ-specific and variable with 2- and 1.5-fold increases in protein expression in kidney and brain, respectively, and a 60% decrease in anoxic spleen. These results for an anoxia-tolerant animal suggest the potential importance of the MAPKs and of the immediate-early genes (c-fos, c-myc) in mediating adaptive responses to oxygen deprivation. (C) 2000 Wiley-Liss, Inc

Differential regulation of the mitochondrial ADP/ATP translocase gene in wood frogs under freezing stress

The gene Aat coding for ADP/ATP translocase (AAT) was cloned from liver of the freeze-tolerant wood frog, Rana sylvatica, via differential screening of a cDNA library from liver of frozen frogs and using probes from control versus frozen frogs. Sequence analysis showed that clone pBfFR07 bearing the AAT cDNA contained a 1318-bp insert with one full length open reading frame. The deduced amino acid sequence included 317 residues, with 81-86% identities to mammalian AAT. A 1750-nt transcript from the Aat gene was detected using pBfFR07 probe and a putative frog AAT of over 30 kDa was visualized by immunoblotting using a polyclonal antibody raised against chicken AAT. Analysis of liver samples from a time course of freezing showed a maximal 4.5-fold increase in mRNA after 8 h with AAT protein peaking in 24-h frozen frogs. Freezing also induced Aat expression in bladder and lung. In liver, mRNA expression also responded positively to anoxia stress but not to experimental dehydration of the animals. These results suggest that AAT induction during freezing may be stimulated by the ischemia that develops when plasma freezes; changes in AAT may contribute to stabilizing energetics in mitochondrial versus cytosolic pools over freeze/thaw cycles