Alterations in mitochondrial RNA expression after renal ischemia

Dormancy and quiescence of skeletal muscle stem cells

The skeletal muscle of vertebrates has a huge regenerative capacity. When destroyed after different types of injury, this organ can regenerate very quickly (less than 20 days following myotoxin injection in the mouse) ad integrum and repeatedly. The cell responsible for this regeneration is the so-called satellite cell, the muscle stem cell that lies on top of the muscle fibre, a giant, multinucleated cell that contains the contractile material. When injected in the muscle, satellite cells can efficiently differentiate into contractile muscle fibres. The satellite cell shows great therapeutic potential; and its regenerative capacity has triggered particular interest in the field of muscular degeneration. In this review we will focus on one particular property of the satellite cell: its quiescence and dormancy. Indeed adult satellite cells are quiescent; they lie between the basal lamina and the basement membrane of the muscle fibre, ready to proliferate, and fuse in order to regenerate myofibers upon injury. It has recently been shown that a subpopulation of satellite cells is able to enter dormancy in human and mice cadavers. Dormancy is defined by a low metabolic state, low mobility, and a long lag before division when plated in vitro, compared to quiescent cells. This definition is also based on current knowledge about long-term hematopoietic stem cells, a subpopulation of stem cells that are described as dormant based on the same criteria (rare division and low metabolism when compared to progeny which are dividing more often). In the first part of this review, we will provide a description of satellite cells which addresses their quiescent state. We will then focus on the uneven distribution of satellite cells in the muscle and describe evidence that suggests that their dormancy differs from one muscle to the next and that one should be cautious when making generalisations regarding this cellular state. In a second part, we will discuss the transition between active dividing cells in developing animals to quiescence. This mechanism could be used or amplified in the switch from quiescence to dormancy. In a third part, we will review the signals and dynamics that actively maintain the satellite cell quiescent. The in-depth understanding of these mechanisms is key to describing how dormancy relies on quiescent state of the cells. In a fourth part, we will deal with dormancy per se: how dormant satellite cells can be obtained, their characteristics, their metabolic profile, and their molecular signature as compared to quiescent cells. Here, we will highlight one of the most important recent findings: that quiescence is a prerequisite for the entry of the satellite cell into dormancy. Since dormancy is a newly discovered phenomenon, we will review the mechanisms responsible for quiescence and activation, as these two cellular states are better known and key to understanding satellite cell dormancy. This will allow us to describe dormancy and its prerequisites.

Effects of dietary factors on the pharmacokinetics of 58Fe-labeled hemin after oral administration in normal rats and the iron-deficient rats

Hemin, iron (III) protoporphyrin chloride (IX), as a stable form of heme iron, has been used in iron absorption studies. The aim of the present study was to elucidate the influences of body iron status and three dietary factors (green tea extract, ascorbic acid, and calcium) on the pharmacokinetics of hemin using stable isotope labeling methods followed by ICP-MS measurement. In this study, a rapid, sensitive, and specific ICP-MS method for the determination of (58)Fe originating from hemin in rat plasma was developed and a rat model of iron deficiency anemia was established. It was found that hemin iron absorption increased significantly under iron deficiency anemia status, with AUC0-t and AUC0-∞ showing significant increase in anemic rats compared to normal ones. Green tea extract strongly inhibited hemin iron absorption in both normal rats and iron-deficient rats. In normal rats administered with green tea extract, C max resulted significantly reduced, whereas in anemic rats administered with green tea extract both AUC0-t and AUC0-∞ were reduced. On the other hand, ascorbic acid significantly affected hemin iron absorption only in iron-deficient rats, in which C max showed a significant increase. Interestingly, calcium slowed down the hemin iron absorption rate in normal rats, MRT0-t being significantly different in calcium-treated animals compared to untreated ones. This trend also appeared in the iron-deficient group but it did not reach statistical significance. Our data suggest that the mechanism of hemin iron absorption is regulated by body iron status and dietary factors can influence hemin iron absorption to varying degrees. Moreover, these results may also have general implication in the iron deficiency treatment with iron supplements and fortification of foods.

Novel chelators for cancer treatment: where are we now?

SIGNIFICANCE

Under normal circumstances, cellular iron levels are tightly regulated due to the potential toxic effects of this metal ion. There is evidence that tumors possess altered iron homeostasis, which is mediated by the perturbed expression of iron-related proteins, for example, transferrin receptor 1, ferritin and ferroportin 1. The de-regulation of iron homeostasis in cancer cells reveals a particular vulnerability to iron-depletion using iron chelators. In this review, we examine the absorption of iron from the gut; its transport, metabolism, and homeostasis in mammals; and the molecular pathways involved. Additionally, evidence for alterations in iron processing in cancer are described along with the perturbations in other biologically important transition metal ions, for example, copper(II) and zinc(II). These changes can be therapeutically manipulated by the use of novel chelators that have recently been shown to be highly effective in terms of inhibiting tumor growth.

RECENT ADVANCES

Such chelators include those of the thiosemicarbazone class that were originally thought to target only ribonucleotide reductase, but are now known to have multiple effects, including the generation of cytotoxic radicals.

CRITICAL ISSUES

Several chelators have shown marked anti-tumor activity in vivo against a variety of solid tumors. An important aspect is the toxicology and the efficacy of these agents in clinical trials.

FUTURE DIRECTIONS

As part of the process of the clinical assessment of the new chelators, an extensive toxicological assessment in multiple animal models is essential for designing appropriate dosing protocols in humans.

Subcellular location of heme oxygenase 1 and 2 and divalent metal transporter 1 in relation to endocytotic markers during heme iron absorption

BACKGROUND AND AIM

Heme is an important dietary micronutrient, although its absorptive mechanisms are poorly understood. One hypothesis suggests enterocytes take up heme by receptor-mediated endocytosis (RME) which then undergoes catabolism by heme oxygenase (HO) inside internalized vesicles. This would require the translocation of HO-1 or HO-2 to endosomes and/or lysosomes and the presence of a transporter, possibly divalent metal transporter 1 (DMT1), to transfer released iron to the cytoplasm. Currently, the location of HO-1 and HO-2 in enterocytes is unknown.

METHODS

We studied the subcellular location of HO-1, HO-2, and DMT1 in the proximal small intestine of rats by confocal immunofluorescence microscopy up to 4 h after a dose of heme or ferrous iron. Double-labeling was performed with endocytotic (EEA1, Lamp1) and structural markers (F-actin).

RESULTS

HO-1 was distributed evenly throughout the cytoplasm of enterocytes and did not colocalize with endocytotic markers in any condition. HO-2 staining remained constant with dosing, presenting as a dense band in the apical cytoplasm that colocalized extensively with endosomes. DMT1 staining was markedly reduced by ferrous iron, but not heme and did not exhibit colocalization with endocytotic markers.

CONCLUSION

The subcellular location of HO-2 is consistent with the RME hypothesis for heme uptake and may suggest a possible role for this enzyme in heme degradation. The lack of translocation of DMT1 with heme dosing suggests another protein may be present to transport iron released from heme.

Differential expression of selected mitochondrial genes in hibernating little brown bats,Myotis lucifugus

High rates of non-shivering thermogenesis by brown adipose tissue accompanied by additional shivering thermogenesis in skeletal muscle provide the powerful reheating of body organs that allows hibernating mammals to return from their state of cold torpor back to euthermic function. Previous studies have suggested that changes to brown adipose mitochondria occur during hibernation and are partially responsible for its capacity for non-shivering thermogenesis. The current study shows that selected mitochondrial enzyme activities are elevated and selected genes and proteins are induced during torpor in brown adipose tissue of the little brown bat, Myotis lucifugus. Cytochrome oxidase activity in brown adipose tissue was more than 3-fold higher during torpor than in euthermic animals. Transcript levels of mitochondria-encoded genes, coxII and nad4, were also 3-4-fold higher during torpor, as evidenced by northern blotting. By contrast, transcripts of these genes were unchanged in skeletal muscle during torpor. Protein levels of carnitine palmitoyl transferase-1beta, an enzyme embedded in the outer membrane of the mitochondria that is the rate-limiting step enzyme in beta-oxidation, were also elevated by 2-fold during torpor in brown adipose but were unchanged in skeletal muscle. Cloning and sequencing of a 624 bp segment of cpt-1beta revealed a number of amino acid substitutions in the bat protein as compared to CPT-1beta from other mammals; these may be beneficial for enzyme function at low body temperatures during torpor. This study provides further evidence for a key role of mitochondria in hibernation.

Current status and perspective of antiangiogenic therapy for cancer: urinary cancer

Angiogenesis is considered a prerequisite for solid tumor growth. Antiangiogenic therapy reduces tumor size and extends host survival in a number of preclinical animal models. However, in humans antiangiogenic therapy is a poor promoter of tumor regression and has shown minimal effect on patient survival. In urinary cancers, such as renal cell cancer, prostate cancer, and bladder cancer, advanced refractory disease is a good candidate for antiangiogenic therapy because of its resistance to ordinary chemotherapy, radiotherapy, and hormonal therapy. Unique characteristics of molecular mechanisms underlie the induction of angiogenesis in urinary cancers. In this review, we summarize these unique mechanisms and review the results of clinical trials of antiangiogenic therapy for these cancers, discussing prospects and problems relating to antiangiogenic therapy.

Oxygen tension regulates mitochondrial DNA-encoded complex I gene expression

Oxygen is a major regulator of nuclear gene expression. However, although mitochondria consume almost all of the O2 available to the cells, little is known about how O2 tension influences the expression of the mitochondrial genome. We show in O2-sensitive excitable rat PC12 cells that, among the mtDNA-encoded genes, hypoxia produced a specific down-regulation of the transcripts encoding mitochondrial complex I NADH dehydrogenase (ND) subunits, particularly ND4 and ND5 mRNAs and a stable mRNA precursor containing the ND5 and cytochrome b genes. This unprecedented effect of hypoxia was fast (developed in <30 min) and fairly reversible and occurred at moderate levels of hypoxia (O2 tensions in the range of 20-70 mm Hg). Hypoxic down-regulation of the mitochondrial complex I genes was paralleled by the reduction of complex I activity and was retarded by iron chelation, suggesting that an iron-dependent post-transcriptional mechanism could regulate mitochondrial mRNA stability. It is known that cell respiration is under tight control by the amount of proteins in mitochondrial complexes of the electron transport chain. Therefore, regulation of the expression of the mitochondrial (mtDNA)-encoded complex I subunits could be part of an adaptive mechanism to adjust respiration rate to the availability of O2 and to induce fast adaptive changes in hypoxic cells.

Mechanisms of Haem and Non-Haem Iron Absorption: Lessons from Inherited Disorders of Iron Metabolism

Our current state of knowledge of the mechanism and regulation of intestinal iron absorption has been critically dependent on the analysis of inherited disorders of iron homeostasis in both humans and other animal species. Mutations in DMT1 and Ireg1 have revealed that these molecules are major mediators of iron transport across the brush border and basolateral membranes of the enterocyte, respectively. Similarly, the iron oxidase hephaestin has been shown to play an important role in basolateral iron efflux. The analysis of a range of human iron loading disorders has provided very strong evidence that the products of the HFE, TfR2, hepcidin and hemojuvelin genes comprise integral components of the machinery that regulates iron absorption and iron traffic around the body. Engineered mouse strains have already proved very effective in helping to dissect pathways of iron homeostasis, and in the future they will continue to provide important insights into the absorption of both inorganic and haem iron by the gut.

Hypothermia preserves myocardial function and mitochondrial protein gene expression during hypoxia

Hypothermia before and/or during no-flow ischemia promotes cardiac functional recovery and maintains mRNA expression for stress proteins and mitochondrial membrane proteins (MMP) during reperfusion. Adaptation and protection may occur through cold-induced change in anaerobic metabolism. Accordingly, the principal objective of this study was to test the hypothesis that hypothermia preserves myocardial function during hypoxia and reoxygenation. Hypoxic conditions in these experiments were created by reducing O2 concentration in perfusate, thereby maintaining or elevating coronary flow (CF). Isolated Langendorff-perfused rabbit hearts were subjected to perfusate (Po2 = 38 mmHg) with glucose (11.5 mM) and perfusion pressure (90 mmHg). The control (C) group was at 37 degrees C for 30 min before and 45 min during hypoxia, whereas the hypothermia (H) group was at 29.5 degrees C for 30 min before and 45 min during hypoxia. Reoxygenation occurred at 37 degrees C for 45 min for both groups. CF increased during hypoxia. The H group markedly improved functional recovery during reoxygenation, including left ventricular developed pressure (DP), the product of DP and heart rate, dP/dtmax, and O2 consumption (MVo2) (P < 0.05 vs. control). MVo2 decreased during hypothermia. Lactate and CO2 gradients across the coronary bed were the same in C and H groups during hypoxia, implying similar anaerobic metabolic rates. Hypothermia preserved MMP betaF1-ATPase mRNA levels but did not alter adenine nucleotide translocator-1 or heat shock protein-70 mRNA levels. In conclusion, hypothermia preserves cardiac function after hypoxia in the hypoxic high-CF model. Thus hypothermic protection does not occur exclusively through cold-induced alterations in anaerobic metabolism.

Molecular mechanisms and regulation of iron transport

Iron homeostasis is primarily maintained through regulation of its transport. This review summarizes recent discoveries in the field of iron transport that have shed light on the molecular mechanisms of dietary iron uptake, pathways for iron efflux to and between peripheral tissues, proteins implicated in organellar transport of iron (particularly the mitochondrion), and novel regulators that have been proposed to control iron assimilation. The transport of both transferrin-bound and nontransferrin-bound iron to peripheral tissues is discussed. Finally, the regulation of iron transport is also considered at the molecular level, with posttranscriptional, transcriptional, and posttranslational control mechanisms being reviewed.

Differential expression of mitochondria-encoded genes in a hibernating mammal

A cDNA library constructed from kidney of the thirteen-lined squirrel, Spermophilus tridecemlineatus, was differentially screened for genes that were upregulated during hibernation. A clone encoding cytochrome c oxidase subunit 1 was found and confirmed to have been upregulated by northern blotting. Differential expression of Cox1 mRNA occurred in multiple organs during hibernation; in hibernating animals transcript levels were twofold higher in kidney and fourfold higher in heart and brown adipose tissue than in euthermic animals, but were unchanged in skeletal muscle. Transcript levels of mitochondrial-encoded ATP synthase 6/8 were similarly upregulated in these tissues whereas transcript levels of the nuclear encoded subunits Cox4 and ATP synthase α did not change during hibernation. Immunoblot analysis revealed a 2.4-fold increase in Cox 1 protein and a slight decrease in Cox 4 protein in kidney of hibernating squirrels, compared with euthermic controls. Hibernating mammals may increase the expression of the mitochondrial genome in general, and Cox1specifically, to prevent or minimize the damage to the electron transport chain caused by the cold and ischemia experienced during a hibernation bout.

The effect of cysteine and 2,4-dinitrophenol on heme and nonheme absorption in a rat intestinal model

Previous studies have showed that purified heme iron forms insoluble polymers that are poorly absorbed. The presence of peptides and of amino acids maintaining heme iron in a soluble form could improve its bioavailability. The digestive uptake and transfer of a concentrated hydrolysate of heme peptides (HPH) and of iron gluconate (Gluc) at 100 µM were compared in vitro in a Ussing chamber. The effects of an enhancing amino acid (L-cysteine) on the uptake and transfer of both forms were assessed. An inhibitor of the oxidative phosphorylation (2,4-dinitrophenol; DNP) was used to differentiate the active and passive mechanisms of the absorption. The mucosal uptake (%Tot) and enterocyte transfer (%S) of the two sources of iron did not differ. DNP significantly reduced %Tot and %S of both forms. Cysteine significantly enhanced %Tot and %S of HPH and Gluc, partly corrected the inhibition exerted by DNP on %Tot of HPH and %S of both forms, and fully restored %Tot of Gluc. In presence of peptides produced by globin hydrolysis, the absorption of hemoglobin iron was efficient; it was mostly energy dependent and, therefore, should have occurred by a regulated transcellular pathway. Cysteine enhanced the passive uptake of iron and the passive processes involved in the enterocyte transfer of the common pool made of both sources (heme and nonheme) of iron. These results showed that heme iron can be purified and concentrated without impairing its digestive absorption, provided it remains in presence of peptides or amino acids.

Gene up-regulation in heart during mammalian hibernation

A cDNA library prepared from heart of hibernating golden-mantled ground squirrels, Spermophilus lateralis, was differentially screened to clone genes that were up-regulated during hibernation. Two differentially expressed clones were found after three rounds of screening and were confirmed as up-regulated by Northern blotting. Clone Ang6 encoded a polypeptide with 116 amino acids that was identified as the ventricular isoform of myosin light chain 1 (MLC1(v)). Clone Ang19 coded for 274 amino acid residues of the mitochondrially encoded protein subunit 2 of NADH-ubiquinone oxidoreductase (ND2). Both proteins showed high amino acid sequence identity with their human counterparts, 97.5% for MLC1(v) and 66% for ND2. Northern blot hybridization revealed differential expression of these genes in multiple organs during hibernation. Transcript levels of both were approximately twofold higher in heart and three- to fourfold higher in skeletal muscle of hibernating, versus euthermic, animals. ND2 was also up-regulated in hibernator liver. Hibernation-induced up-regulation of MLC1(v) suggests that a restructuring of myosin subunit composition could contribute to changes in muscle contractility needed for hypothermic function, whereas changes in ND subunit composition may affect the function of the electron transport chain during hibernation.

Hypothermia preserves function and signaling for mitochondrial biogenesis during subsequent ischemia

Hypothermia is known to protect myocardium during ischemia, but its role in induction of a protective stress response before ischemia has not been evaluated. As cold incites stress responses in other tissues, including heat shock protein induction and signaling mitochondrial biogenesis, we postulated that hypothermia in perfused hearts would produce similar phenomena while reducing injury during subsequent ischemia. Studies were performed in isolated perfused rabbit hearts (n = 77): a control group (C) and a hypothermic group (H) subjected to decreasing infusate temperature from 37 to 31 degrees C over 20 min. Subsequent ischemia during cardioplegic arrest at 34 degrees C for 120 min was followed by reperfusion. At 15 min of reperfusion, recovery of left ventricular developed pressure (LVDP), maximum first derivative of left ventricular pressure (LV dP/dtmax), LV -dP/dtmax, and the product of heart rate and LVDP was significantly increased in H (P < 0.01) compared with C hearts. Ischemic contracture started later in H (97.5 +/- 3.6 min) than in C (67.3 +/- 3.3 min) hearts. Myocardial ATP preservation and repletion during ischemia and reperfusion were higher in H than in C hearts. mRNA levels of the nuclear-encoded mitochondrial proteins adenine nucleotide translocase isoform 1 (ANT1) and beta-F1-adenosine-triphosphatase (beta-F1-ATPase) normalized to 28S RNA decreased in C hearts but were preserved in H hearts after reperfusion. Inducible heat shock protein (HSP70-1) mRNA was elevated nearly 4-fold after ischemia in C hearts and 12-fold in H hearts. These data indicate that hypothermia preserves myocardial function and ATP stores during subsequent ischemia and reperfusion. Signaling for mitochondrial biogenesis indexed by ANT1 and beta-F1-ATPase mRNA levels is also preserved during a marked increase in HSP70-1 mRNA.

Regulation of mammalian iron metabolism: current state and need for further knowledge

Due to its character as an essential element for all forms of life, the biochemistry and physiology of iron has attracted very intensive interest for many decades. In more recent years, the ways that iron metabolism is regulated in mammalian and human organisms have been clarified, and many aspects of iron metabolism have been reviewed. In this article, some newer aspects concerning absorption and intracellular regulation of iron concentration are considered. These include a sorting of possible models for intestinal iron absorption, a description of ways for membrane passage of iron after release from transferrin during receptor-mediated endocytosis, a consideration of possible mechanisms for non-transferrin bound iron uptake and its regulation, and a review of recent knowledge on the properties of iron regulatory proteins and on regulation of iron metabolism by these proteins, changes of their own properties by non-iron-mediated influences, and regulatory events not mediated by these proteins. This somewhat heterogeneous collection of themes is a consequence of the intention to avoid repetition of the many aforementioned reviews already existing and to concentrate on newer findings generated within the last couple of years.

Activity of keratinocyte growth factor-like substance extracted from rabbit liver on renal tubular cell growth during compensatory renal hyperplasia

BACKGROUND

In response to unilateral nephrectomy, the rabbit liver transiently produces 2 growth regulators for cultured renal cortical tubular cells: a tubular cell growth factor and a growth inhibitor. We report on the effects of the tubular cell growth factor on a variety of cell lines.

METHODS

The tubular cell growth factor activity was partially purified from the rabbit liver by using gel filtration and ion-exchange chromatography. The activity was monitored by the incorporation of iododeoxyuridine into DNA of cultured cells. Expression of the fibroblast growth factor receptor-2 in the rabbit kidney was determined by the immunoblot analysis.

RESULTS

This growth factor stimulated the DNA synthesis in LLC-PK1 cells, LLC-RK1 cells, and human keratinocytes. It did not affect the growth of BS-C-1 cells, MDCK cells, BALB/c 3T3 fibroblasts, or rat parenchymal hepatocytes. The additive effect of this factor on the DNA synthesis of cultured tubular cells maximally was stimulated by insulin-like growth factor-I, basic fibroblast growth factor, and epidermal growth factor, but was not stimulated by keratinocyte growth factor. The amount of this activity also increased in the liver after sham operation. In the days after surgery, expression of fibroblast growth factor receptor-2, which includes the keratinocyte growth factor receptor, was down-regulated in the kidneys of both uninephrectomized and sham-operated rabbits.

CONCLUSION

These findings indicate that tubular cell growth factor in the liver seems to be a keratinocyte growth factor, and acts in an endocrine manner in renal tubular hyperplasia.

Activity-dependent regulation of cytochrome b gene expression in monkey visual cortex

The recent demonstration that certain mitochondrial subunits of cytochrome oxidase (CO) are regulated by neuronal activity has stimulated interest in the molecular processes that coordinate nuclear and mitochondrial gene expression following synaptic stimulation. We have studied the constitutive expression and activity-guided regulation of cytochrome b (cyt b), a gene that is encoded by mitochondrial DNA and that was cloned by subtractive hybridization from the lateral geniculate nucleus in the monkey. We have found cyt b mRNA expression in monkey striate cortex to be similar to that of CO activity with regard to the laminar profile and the presence of blobs in the supragranular layers. Layers 2/3, 4C, and 6 contained large numbers of stained cells, many of which were judged to be excitatory neurons, because they showed a Zif268-immunopositive nucleus. We have also found that removal of functional activity reduced cyt b mRNA content in area V1. Columns of reduced cyt b staining were visible after 3 days and were especially striking after 6 days of monocular deprivation. After 3 months of deprivation, the columns lost their contrast and became blurred. Our principal finding, that neuronal activity regulates cyt b levels, suggests that expression of a mitochondrial gene can be affected in a manner similar to that of several known nuclear genes. The differences in cyt b mRNA levels and CO activity after long-term deprivation suggests that some form of differential control is exerted on cyt b. Cyt b expression, therefore, may be used as a marker of altered mitochondrial transcription that is guided by the metabolic demands of active neurons.

Anoxia-induced gene expression in turtle heart. Upregulation of mitochondrial genes for NADH-ubiquinone oxidoreductase subunit 5 and cytochrome c oxidase subunit 1

A cDNA library constructed from heart of anoxia-exposed adult turtles (Trachemys scripta elegans) was differentially screened with 32P-labeled single-stranded cDNA probes from heart of control versus anoxic animals to clone genes induced by anoxia stress. Four cDNA clones, pBTaR20, pBTaR34, pBTaR63 and pBTaR914 were obtained and confirmed to be upregulated in response to anoxic submergence (20 h in N2-bubbled water at 7 degrees C). Two clones, pBTaR20 and pBTaR63, were characterized by sequence analysis and in vivo expression. The clone pBTaR20 had a 1597-bp cDNA sequence and pBTaR63 contained a 1837-bp sequence. The pBTaR20 sequence contained a single open reading frame that was very close to full length and could potentially encode a polypeptide with 508 amino acids. The deduced polypeptide sequence showed approximately 83% of the residues identical with the sequence of cytochrome c oxidase subunit 1 (CO1) that is encoded by a mtDNA gene Cox1. The clone pBTaR63 contained a single potentially full-length open reading frame that could encode a polypeptide of 591 residues. This was similar to another mitochondrial protein, NADH-ubiquinone oxidoreductase subunit 5 (ND5), which is encoded by mtDNA gene Nad5. Analysis of the time course of expression of Cox1 and Nad5 by northern hybridization analysis showed that mRNA transcripts for both accumulated rapidly (within 1 h) in response to anoxia exposure. Both showed similar increases in their transcript content after 1 h of anoxia but with longer anoxia exposures (5 or 20 h) Nad5 mRNA levels remained high whereas Cox1 mRNA content declined somewhat. Northern-blot hybridization also revealed differential expression of these two genes in five other organs of T. s. elegans during anoxia exposure (brain, kidney, liver, red and white skeletal muscle), with a particularly large increase in mRNA transcript levels of both genes in anoxic red muscle. Organ-specific analysis of these genes in a freeze-tolerant turtle species (Chrysemys picta marginata) also showed that differential expression of these genes occurred in response to the ischemia induced by plasma freezing.

Magnesium cardioplegia enhances mRNA levels and the maximal velocity of cytochrome oxidase I in the senescent myocardium during global ischemia

BACKGROUND

The aged myocardium accumulates significantly more cytosolic calcium [Ca2+]i during ischemia, and functional recovery is more severely compromised as compared with the mature heart. Cardioplegia ameliorates these phenomena. The mechanism by which increased calcium accumulation reduces functional recovery in the senescent myocardium is unknown, but it has been suggested that futile calcium cycling in the mitochondria leading to depletion of ATP stores during normothermic global ischemia may be involved.

METHODS AND RESULTS

To investigate the effect of cardioplegia on mitochondrial calcium ([Ca2+]mt) accumulation and the expression of cytochrome oxidase I (COX I) during global ischemia, mitochondria were isolated from mature (age, 15 to 20 weeks) and aged (age > 130 weeks) rabbit hearts after Langendorff perfusion. Five perfused heart groups were investigated: 30 minutes of global ischemia without treatment (control), with potassium (K, 20 mmol/L), magnesium (Mg, 20 mmol/L), or potassium and magnesium (K/Mg) cardioplegia. No significant difference in [Ca2+]mt was evident in mature hearts with any protocol. In aged hearts, [Ca2+]mt was increased in global ischemia but was ameliorated with Mg and K/Mg cardioplegia. COX I mRNA levels in aged hearts were lower in both control and global ischemia but were increased with cardioplegia. Maximal velocities for COX I were significantly increased with Mg cardioplegia both in the mature and the aged myocardium.

CONCLUSIONS

K and/or Mg cardioplegia ameliorates [Ca2+]mt accumulation in aged hearts during normothermic global ischemia and increases COX I mRNA levels to a level not significantly different from that found in mature hearts.