Effects of ATP-MgCl2 and adenosine-MgCl2 administration on intracellular ATP levels in the kidney

The effects of exogenous administration of 1 mM [8-14C]ATP-MgCl2 and adenosine-MgCl2 on intracellular accumulation of adenine nucleotides were examined in isolated, perfused rat kidneys. The kidneys were made filtering or non-filtering by increasing the colloid oncotic pressure of the perfusate solution in order to assess the relative contributions of the glomerular and peritubular routes in the uptake of the nucleotides. The results indicate that: although labeled ATP is undetectable in the perfusate after 20 min, there is a significant accumulation of labeled ATP in the tissue and although labeled adenosine-MgCl2 administration also leads to labeled intracellular ATP, the total intracellular ATP is much less than with ATP-MgCl2 administration.     

Exacerbated brain damage, edema and inflammation in type-2 diabetic mice subjected to focal ischemia

One of the limiting factors in stroke therapeutic development is the use of animal models that do not well represent the underlying medical conditions of patients. In humans, diabetes increases the risk of stroke incidence as well as post-stroke mortality. To understand the mechanisms that render diabetics to increased brain damage, we evaluated the effect of transient middle cerebral artery occlusion in adult db/db mice. The db/db mouse is a model of type-2 diabetes with four times higher blood sugar than its normoglycemic genetic control(db/+ mouse). Following transient middle cerebral artery occlusion, the db/db mice showed significantly higher mortality, bigger infarcts, increased cerebral edema, worsened neurological status compared to db/+ mice. The db/db mice also showed significantly higher post-ischemic inflammatory markers (ICAM1(+) capillaries, extravasated macrophages/neutrophils and exacerbated proinflammatory gene expression) compared to db/+ mice. In addition, the post-ischemic neuroprotective heat-shock chaperone gene expression was curtailed in the db/db compared to db/+ mice.     

Hypertension,hypokalemia, hyporeninemia and severe target organ damage.

A 51-year-old woman with a 20-year history of severe hypertension and target organ damage had nondiuretic hypokalemia, kaluresis, suppressed plasma renin activity and elevated urinary excretion of aldosterone. Renal arteriography demonstrated unilateral renal artery stenosis secondary to fibromuscular hyperplasia. Blood pressure responded only minimally to almost all antihypertensive agents. Spironolactone, 300 to 400 mg/d, produced distinct improvement in blood pressure, which was maintained for 13 months.     

Selective pulmonary vasodilation with ATP-MgCl2 during pulmonary hypertension in lambs

We investigated the effects of infusions of ATP-MgCl2 on the circulation in 11 spontaneously breathing newborn lambs during pulmonary hypertension induced either by the infusion of U-46619, a thromboxane A2 mimetic, or by hypoxia. During pulmonary hypertension induced by U-46619, ATP-MgCl2 (0.01-1.0 mg.kg-1.min-1) caused a significant dose-dependent decrease in pulmonary arterial pressure (12.4-40.7%, P less than 0.05), while systemic arterial pressure decreased only at the highest doses (P less than 0.05). Left atrial infusions of ATP-MgCl2 caused systemic hypotension without decreasing pulmonary arterial pressure. During hypoxia-induced pulmonary hypertension, ATP-MgCl2 caused a similar significant dose-dependent decrease in pulmonary arterial pressure (12.0-41.1%, P less than 0.05), while systemic arterial pressure decreased only at high doses (P less than 0.05). Regression analysis showed selectivity of the vasodilating effects of ATP-MgCl2 for the pulmonary circulation during pulmonary hypertension induced either by U-46619 or hypoxia. ATP-MgCl2 is a potent vasodilator with a rapid metabolism that allows for selective vasodilation of the vascular bed first encountered (pulmonary or systemic). We conclude that infusions of ATP-MgCl2 may be clinically useful in the treatment of children with pulmonary hypertension.     

ATP-MgCl2 restores renal microcirculation following trauma and severe hemorrhage.

Although ATP-MgCl2 enhances the recovery of renal function after ischemia and reperfusion, it is not known whether this agent has any beneficial effects on renal microcirculation and function in a nonheparinized model of trauma and severe hemorrhage. To study this, a midline laparotomy was performed (i.e., trauma induced) and the rats were bled to and maintained at a mean arterial pressure of 40 mmHg (1 mmHg = 133.32 Pa) until 40% of the maximum shed blood volume was returned in the form of Ringer's lactate (RL) solution. Animals were then resuscitated with 4 times the volume of the shed blood in the form of RL. ATP-MgCl2, 50 mumol/kg body weight, or an equivalent volume of saline, was infused intravenously during and following resuscitation. Renal microcirculation was examined by using colloidal carbon infusion and laser Doppler flow-metry. Glomerular filtration rate (GFR) was assessed with [3H]inulin clearance and cardiac output (CO) was determined by dye dilution technique. The results indicate that the depressed renal microcirculation following hemorrhage and resuscitation was restored by ATP-MgCl2 treatment. GFR was significantly higher in ATP-MgCl2-treated than saline-treated rats. ATP-MgCl2 also increased urine output, restored the decreased CO, and prevented the occurrence of renal edema after hemorrhage and resuscitation. Thus, ATP-MgCl2 appears to be a useful adjunct to crystalloid resuscitation following trauma and severe hemorrhagic shock even in the absence of blood resuscitation.     

Gut mucosal damage during endotoxic shock is due to mechanisms other than gut ischemia.

Whether the gut alterations seen during sepsis are caused by microcirculatory hypoxia or disturbances in cellular metabolic pathways associated with mitochondrial respiration remains controversial. We hypothesized that hypoperfusion or hypoxia and local production of nitric oxide might play an important role in the development of gut mucosal injury during endotoxic shock and investigated their roles by using differing levels of fluid resuscitation and occlusion of the superior mesenteric artery (SMA). Anesthetized New Zealand rabbits were allocated to group I (sham, n = 8); group II [low-dose endotoxin (LPS, Escherichia coli-055:B5, 150 microg/kg)/fluid resuscitation (12 ml x kg(-1) x h(-1)); n = 8]; group III [high-dose LPS (1 mg/kg)/fluid resuscitation (12 ml x kg(-1) x h(-1)); n = 8]; group IV [high-dose LPS (1 mg/kg)/hypovolemia (4 ml x kg-1 x h(-1) fluids); n = 8]; and group V [SMA ligation/fluid resuscitation (12 ml x kg(-1) x h(-1)); n = 4]. Luminal gut lactate concentrations and PCO2 gap increased in groups IV and V (P < 0.05), reflecting alterations in gut perfusion. Interestingly, significant histological alterations were observed in all LPS groups but not in group V. Blood and luminal gut nitrate/nitrite concentrations increased only in group IV. The mechanism of gut injury in endotoxic shock seems unrelated to hypoxia and release of nitric oxide. Gut dysfunction may occur as a result of so-called "cytopathic hypoxia."     

Eicosanoids as mediators of ischemia and shock

A variety of eicosanoids are produced in ischemic and circulatory shock. Many of these constrict arteries, induce platelet aggregation or adherence of other blood cells to the vasculature, and contribute to increased membrane permeability. Thromboxane A2, leukotriene C4, and leukotriene D4 fulfill all the criteria stipulated for humoral mediators of ischemia and shock. Moreover, pharmacologic modulation of these mediators by either specific inhibition of their synthesis or antagonism of their arteries at their receptor sites protects against tissue and cell damage during ischemia and shock as well as enhances survival in these life-threatening states.     

Sex differences in baroreflex sensitivity, heart rate variability, and end organ damage in the TGR(mRen2)27 rat

The aim of this investigation was to evaluate sex differences in baroreflex and heart rate variability (HRV) dysfunction and indexes of end-organ damage in the TG(mRen2)27 (Ren2) rat, a model of renin overexpression and tissue renin-angiotensin-aldosterone system overactivation. Blood pressure (via telemetric monitoring), blood pressure variability [BPV; SD of systolic blood pressure (SBP)], spontaneous baroreflex sensitivity, HRV [HRV Triangular Index (HRV-TI), standard deviation of the average NN interval (SDNN), low and high frequency power (LF and HF, respectively), and Poincaré plot analysis (SD1, SD2)], and cardiovascular function (pressure-volume loop analysis and proteinuria) were evaluated in male and female 10-wk-old Ren2 and Sprague Dawley rats. The severity of hypertension was greater in Ren2 males (R2-M) than in Ren2 females (R2-F). Increased BPV, suppression of baroreflex gain, decreased HRV, and associated end-organ damage manifested as cardiac dysfunction, myocardial remodeling, elevated proteinuria, and tissue oxidative stress were more pronounced in R2-M compared with R2-F. During the dark cycle, HRV-TI and SDNN were negatively correlated with SBP within R2-M and positively correlated within R2-F; within R2-M, these indexes were also negatively correlated with end-organ damage [left ventricular hypertrophy (LVH)]. Furthermore, within R2-M only, LVH was strongly correlated with indexes of HRV representing predominantly vagal (HF, SD1), but not sympathetic (LF, SD2), variability. These data demonstrated relative protection in females from autonomic dysfunction and end-organ damage associated with elevated blood pressure in the Ren2 model of hypertension.     

Heat shock protein 72 overexpression protects against hyperthermia, circulatory shock, and cerebral ischemia during heatstroke.

This study extends our earlier studies in rats by applying our heatstroke model to a new species. Additionally, transgenic mice are used to examine the role of heat shock protein (HSP) 72 in experimental heatstroke. Transgenic mice that were heterozygous for a porcine HSP70i gene ([+]HSP72), transgene-negative littermate controls ([-]HSP72), and normal Institute of Cancer Research strain mice (ICR) under pentobarbital sodium anesthesia were subjected to heat stress (40 degrees C) to induce heatstroke. In [-]HSP72 or ICR, the values for mean arterial pressure, the striatal blood flow, and the striatal PO2 after the onset of heatstroke were significantly lower than those in preheat controls. The core and brain temperatures, the extracellular concentrations of ischemic and injury markers in the striatum, and the striatal neuronal damage scores were significantly greater than those in the preheat controls. In [-]HSP72 or ICR, the body temperatures, cell ischemia content, and injury marker in the striatum were significantly higher, and the mean arterial pressure, striatal blood flow, and striatal PO2 concentration were significantly lower during heatstroke than in [+]HSP72. Accordingly, the latency and the survival times for [+]HSP72 significantly exceeded those of [-]HSP72 or ICR. These results demonstrate that the overexpression of HSP72 in multiple organs improves survival during heatstroke by reducing hyperthermia, circulatory shock, and cerebral ischemia and damage in mice.     

Endothelial heat shock response in cerebral ischemia

Blood vessels and nerve fibers often course alongside one another in an orderly fashion throughout the brain. This clustering gives rise to a reciprocal signaling network between endothelial and nerve cells that follows highly stereotyped anatomical patterns. One such molecular signal that is produced by endothelial cells and acts on surrounding neurons is heat shock protein 70. Here we briefly review recent studies that have revealed a critical role of this signaling pathway during harmful insults to the brain, particularly during episodes of cerebral ischemia.     

Glutamate release and neuronal damage in ischemia.

Neuronal injury caused by ischemia after occlusion of cerebral arteries is believed to be mediated by excessive activation of glutamate receptors. In the ischemic brain, extracellular glutamate is elevated rapidly after the onset of ischemia and declines following reperfusion. The mechanisms of the elevation of extracellular glutamate include enhanced efflux of glutamate and the reduction of glutamate uptake. The early efflux of glutamate occurring immediately after the onset of ischemia is mediated by a calcium-dependent process through activation of voltage-dependent calcium channels. The calcium-independent efflux at later stages is thought to be mediated primarily by glutamate transporters operating in the reverse mode owing to the imbalance of sodium ions across plasma membranes. Although high levels of glutamate in the extracellular space are well established to appear rapidly after the onset of ischemia, a direct linkage between the enhanced release of glutamate and the neuronal injury has not been fully established. In cultured neurons, ischemia induces efflux of glutamate into the extracellular space, but subsequent neuronal loss is not solely caused by the high glutamate concentration. In addition, cultured neurons can be rescued by NMDA antagonists added to the medium after exposure to glutamate receptor agonists. Two mechanisms can be proposed for neuroprotection by late NMDA receptor blockade, i.e., blocking of presynaptic release of glutamate after excessive activation of glutamate receptors, and blocking of postsynaptic sensitization of NMDA receptors.     

Expression of calcineurin,calpastatin and heat shock proteins during ischemia and reperfusion

ObjectiveCalcineurin (CaN) interacts with calpains (Calpn) and causes cellular damage eventually leading to cell death. Calpastatin (Calp) is a specific Calpn inhibitor, along with CaN stimulation has been implicated in reduced cell death and self-repair. Molecular chaperones, heat shock proteins (Hsp70 and Hsp90) acts as regulators in Calpn signaling. This study aims to elucidate the role of CaN, Calp and Hsps during induced ischemia and reperfusion in primary cardiomyocyte cultures (murine).Methods and resultsProtein expression was analyzed concurrently with viability using flow cytometry (FACS) in ischemia- and reperfusion-induced murine cardiomyocyte cultures. The expression of Hsp70 and Hsp90, both being molecular chaperones, increased during ischemia with a concurrent increase in death of cells expressing these proteins. The relative expression of Hsp70 and Hsp90 during ischemia with respect to CaN was enhanced in comparison to Calp. Reperfusion slightly decreased the number of cells expressing these chaperones. There was no increase in death of cells co-expressing Hsp70 and Hsp90 along with CaN and Calp. CaN expression peaked during ischemia and subsequent reperfusion reduced its expression and cell death. Calp expression increased both during ischemia and subsequent reperfusion but cell death decreased during reperfusion.ConclusionThe present study adds to the existing knowledge that Hsp70, Hsp90, CaN and Calp interact with each other and play significant role in cardio protection.     

Protection of boar spermatozoa from cold shock damage by 2-hydroxypropyl-beta-cyclodextrin

This study examined whether 2-hydroxypropyl-beta-cyclodextrin (HBCD) could play a role in protecting spermatozoa from cold shock, as judged by motility parameters, intact acrosomes, and membrane integrity. Motility parameters were assessed by a computer-assisted sperm motility analysis (CASA) system, and the acrosome and membrane integrity were evaluated by fluorescent staining with FlTC-labeled peanut agglutinin and SYBR-14 plus Propidium Iodide, respectively. The addition of HBCD to the BF5 extender significantly increased the percentages of spermatozoa with intact acrosomes and increased membrane integrity after cold shock. The motility, progressive motility, and progressive velocity of the cold-shocked spermatozoa in the presence of HBCD were significantly higher than in the absence of HBCD. In contrast, further supplement of HBCD with cholesterol-3-sulfate (a cholesterol analogue) resulted in a decrease in all the aforementioned criteria, suggesting that the ability of HBCD to protect spermatozoa from cold shock injury is blocked by saturating the cholesterol binding sites of HBCD. It is therefore concluded that HBCD protects spermatozoa against cold shock injury, possibly due to its ability to remove membrane cholesterol.