Michael P. Czubryt

The contribution of ionic contribution of ionic imbalance to ischemia/reperfusion-induced injury

Recent data from a number of independent laboratories have implicated ionic disturbances within the myocardium as being a critical contributory factor in injury to the heart during ischemia/reperfusion. The present treatise discusses the data supporting a role for Ca2+, Na+ and K+ in ischemic/reperfusion injury. The mechanism whereby intracellular ionic homeostasis becomes altered is the focus of the review. In particular, the evidence in support of an involvement of abnormal ion movements through Na+/H+ exchange, Na+ channels and the ATP-sensitive K+ channel in ischemic/reperfusion injury is advanced.

The basic helix―loop―helix transcription factor scleraxis regulates fibroblast collagen synthesis

The transcription factor scleraxis has been implicated in regulating the development of collagen-rich tissues such as tendons and cardiac valves, but its role in general collagen synthesis in the heart is unknown. Scleraxis expression in cardiac fibroblasts was examined, and its ability to regulate gene expression of collagen I alpha 2, the predominant cardiac collagen isoform, was assayed. Using real-time PCR, we demonstrate here that scleraxis mRNA is up-regulated by the profibrotic agonist TGF-beta(1) in rat cardiac myofibroblasts, and that phenoconversion of fibroblasts to myofibroblasts similarly increases scleraxis expression. Over-expression of scleraxis in NIH-3T3 or primary rat cardiac fibroblasts by adenoviral gene delivery is sufficient to significantly increase collagen I alpha 2 gene expression. Using luciferase reporter assays, we demonstrate that scleraxis transactivates the human collagen I alpha 2 promoter in a DNA- and protein-binding dependent manner. Intriguingly, examination of infarcted rat hearts reveals a nearly four-fold increase in scleraxis expression in the infarct scar, but not in non-infarcted tissue. These data support a novel and previously unknown role for scleraxis in the regulation of collagen gene expression in the heart, including in post-infarct scar formation.

CALCIUM AND CALCIUM-BINDING PROTEINS IN THE NUCLEUS

Calcium has long been known to play a role as a key cytoplasmic second messenger, but until relatively recently its possible involvement in nuclear signal transduction and the regulation of nuclear events has not been extensively studied. Evidence revealing the presence of transmembrane nuclear Ca2+ gradients and a variety of intranuclear Ca2+ binding proteins has fueled renewed interest in this key ion and its involvement in cell-cycle timing and division, gene expression, and protein activation. This review will offer an overview of the current state of knowledge and theory regarding calcium orchestration of nuclear functions and events and discuss possible future directions in this field of study.

A model of low-flow ischemia and reperfusion in single, beating adult cardiomyocytes.

The present study was undertaken to comprehensively characterize low-flow ischemia and reperfusion in single adult cardiomyocytes and to determine whether it is important to control contractile activity. The ischemia-mimetic solution was hypoxic, acidic (pH 6.0), and deficient in glucose but contained elevated KCl. Cardiomyocytes were stimulated to contract throughout ischemia and during reperfusion with control perfusate. After the ischemia-reperfusion insult, cells exhibited poor recovery of active cell shortening, a decrease in passive cell length, increased frequency of necrosis, lower ATP content, and evidence of the generation of oxygen-derived free radicals within the cells. Intracellular lactate concentration increased, pH decreased, and Ca2+ transients were depressed during the ischemic insult, but the latter two parameters recovered partially on reperfusion. Basal intracellular Ca2+ concentration was elevated during ischemia and early into reperfusion. Recovery was attenuated in cells that were electrically stimulated to contract throughout ischemia. The duration of ischemia, stimulation frequency, and composition of the ischemia-mimetic solution were important variables. The inclusion of 10 mM lactate in the ischemia-mimetic solution significantly aggravated all the parameters examined above. Our data demonstrate that 1) an ischemia-mimetic solution administered to single, isolated adult cardiomyocytes can reproduce many of the responses observed in whole hearts, 2) caution should be used in adding lactate to an ischemic solution, and 3) it is important to stimulate contractile activity throughout ischemia to reproduce the effects of ischemia in whole hearts.The present study was undertaken to comprehensively characterize low-flow ischemia and reperfusion in single adult cardiomyocytes and to determine whether it is important to control contractile activity. The ischemia-mimetic solution was hypoxic, acidic (pH 6.0), and deficient in glucose but contained elevated KCl. Cardiomyocytes were stimulated to contract throughout ischemia and during reperfusion with control perfusate. After the ischemia-reperfusion insult, cells exhibited poor recovery of active cell shortening, a decrease in passive cell length, increased frequency of necrosis, lower ATP content, and evidence of the generation of oxygen-derived free radicals within the cells. Intracellular lactate concentration increased, pH decreased, and Ca(2+) transients were depressed during the ischemic insult, but the latter two parameters recovered partially on reperfusion. Basal intracellular Ca(2+) concentration was elevated during ischemia and early into reperfusion. Recovery was attenuated in cells that were electrically stimulated to contract throughout ischemia. The duration of ischemia, stimulation frequency, and composition of the ischemia-mimetic solution were important variables. The inclusion of 10 mM lactate in the ischemia-mimetic solution significantly aggravated all the parameters examined above. Our data demonstrate that 1) an ischemia-mimetic solution administered to single, isolated adult cardiomyocytes can reproduce many of the responses observed in whole hearts, 2) caution should be used in adding lactate to an ischemic solution, and 3) it is important to stimulate contractile activity throughout ischemia to reproduce the effects of ischemia in whole hearts.

Synergistic roles of scleraxis and Smads in the regulation of collagen 1α2 gene expression.

Cardiac fibrosis is marked by increased deposition of extracellular matrix components including fibrillar collagens, leading to impaired cardiac contractility and function. We recently demonstrated that the transcription factor scleraxis is expressed in collagen-producing cardiac fibroblasts and myofibroblasts, is up-regulated in the collagen-rich scar following myocardial infarction and is sufficient to transactivate the human collagen 1α2 (COL1A2) gene, suggesting a central role in fibrosis. Here we describe the mechanism of scleraxis-mediated regulation of the COL1A2 promoter. Using chromatin immunoprecipitation in primary human cardiac fibroblasts in combination with luciferase assays, we demonstrate that two E box sequences within the proximal COL1A2 promoter are required for scleraxis-mediated transactivation. Expression of scleraxis itself was induced by receptor Smad3, an effector of the pro-fibrotic growth factor TGF-β(1), and attenuated by inhibitory Smad7. TGF-β(1) augmented the effect of scleraxis on COL1A2 transactivation, an effect which was due to synergy between scleraxis and Smad3. Mutation of the COL1A2 Smad-binding element significantly attenuated the ability of scleraxis to transactivate the promoter, while mutation of the scleraxis-interacting E boxes attenuated the effect of Smad3, suggesting that these factors form a common signaling complex at the promoter. COL1A2 promoter transactivation and Col1α2 gene expression in cardiac fibroblasts were completely abrogated by a scleraxis basic domain deletion mutant in a dominant negative fashion, blocking the ability of TGF-β(1) to activate collagen synthesis and suggesting that scleraxis-DNA interaction is absolutely required for this process. Scleraxis thus appears to play a key role in the transcriptional regulation of type I collagen synthesis.

Roles of histone deacetylation and AMP kinase in regulation of cardiomyocyte PGC-1α gene expression in hypoxia

The transcriptional coactivator peroxisome proliferator-activated receptor-γ coactivator-1α (PGC-1α) is a key determinant of cardiac metabolic function by regulating genes governing fatty acid oxidation and mitochondrial biogenesis. PGC-1α expression is reduced in many cardiac diseases, and gene deletion of PGC-1α results in impaired cardiomyocyte metabolism and function. Reduced fuel supply generally induces PGC-1α expression, but the specific role of oxygen deprivation is unclear, and the mechanisms governing PGC-1α gene expression in these situations are poorly understood. During hypoxia of primary rat cardiomyocytes up to 12 h, we found that PGC-1α expression was downregulated via a histone deacetylation-dependent mechanism. Conversely, extended hypoxia to 24 h concomitant with glucose depletion upregulated PGC-1α expression via an AMP-activated protein kinase (AMPK)-mediated mechanism. Our previous work demonstrated that estrogen-related receptor-α (ERRα) regulates PGC-1α expression, and we show here that overexpression of ERRα was sufficient to attenuate PGC-1α downregulation in hypoxia. We confirmed that chronic hypoxia downregulated cardiac PGC-1α expression in a hypoxic but nonischemic hypobaric rat model of pulmonary hypertension. Our data demonstrate that depletion of oxygen or fuel results in repression or induction, respectively, of PGC-1α expression via discrete mechanisms, which may contribute to cardiac energetic derangement during hypoxia, ischemia, and failure.

Oxidation of Nuclear Membrane Cholesterol Inhibits Nucleoside Triphosphatase Activity

Oxygen derived free radicals can oxidize membrane cholesterol. We have previously shown that cholesterol in the nuclear membrane can modulate nuclear nucleoside triphosphatase (NTPase) activity. Nucleocytoplasmic transport of peptides and mRNA via the nuclear pore complex may be regulated by the NTPase. The purpose of the present study was to determine if oxidation of nuclear cholesterol could alter NTPase activity. Nuclear membrane cholesterol was oxidized in situ with cholesterol oxidase (to selectively oxidize cholesterol) and NTPase activity measured. HPLC analysis confirmed the formation of cholesterol oxides. The activity of the NTPase was strikingly inhibited by cholesterol oxidase treatment. The Vmax of the NTPase was significantly decreased after cholesterol oxidase treatment but the Km value was unchanged. The sensitivity of NTPase activity to varying cholesterol oxidase concentrations also suggested that cholesterol located in the inner leaflet of the nuclear membrane appeared to be more important in the modulation of NTPase activity than that in the cytoplasmic leaflet. Our results indicate that oxidation of nuclear membrane cholesterol inhibits NTPase activity. These results have implications for peptide and mRNA flux across the nuclear membrane during conditions where lipid oxidation may be expected.

The nuclear membrane integrity assay

A novel technique is described for the evaluation of membrane integrity in isolated nuclei. Membrane integrity is assessed by measuring nuclear fragility in response to high salt conditions. Salt-induced disruption of the nuclear membrane is followed by spectrophotometric monitoring of released nucleotides. The assay is based on determining the amount of salt necessary to induce release of 50% of the total pool of releasable nucleotides. This allows semiquantitative comparison of relative nuclear membrane strength or integrity of different samples in response to high salt conditions. In this manner, the effects of altered nuclear membrane composition or metabolism on membrane integrity may be monitored.