Volume-regulatory responses of Amphiuma red cells in anisotonic media. The effect of amiloride

Amphiuma red cells were incubated for several hours in hypotonic or hypertonic media. They regulate their volume in both media by using ouabain-insensitive salt transport mechanisms. After initially enlarging osmotically, cells in hypotonic media return toward their original size by losing K, Cl, and H2O. During this volume-regulatory decrease (VRD) response, K loss results from a greater than 10-fold increase in K efflux. Cells in hypertonic media initially shrink osmotically, but then return toward their original volume by gaining Na, Cl, and H2O. The volume-regulatory increase (VRI) response involves a large (greater than 100-fold) increase in Na uptake that is entirely blocked by the diuretic amiloride (10(-3) M). Na transport in the VRI response shares many of the characteristics of amiloride-sensitive transport in epithelia: (a) amiloride inhibition is reversible; (b) removal of amiloride from cells pretreated with amiloride enhances Na uptake relative to untreated controls; (c) amiloride appears to act as a competitive inhibitor (Ki = 1-3 microM) of Na uptake; (d) Na uptake is a saturable function of external Na (Km approximately 29 mM); (e) Li can substitute for Na but K cannot. Anomalous Na/K pump behavior is observed in both the VRD and the VRI responses. In the VRD response, pump activity increases 3-fold despite a decrease in intracellular Na concentration, while in the VRI response, a 10-fold increase in pump activity is observed when only a doubling is predicted from increases in intracellular Na.     

Regulation of sheep erythrocyte volume in anisotonic media.

Sheep erythrocytes of high and low potassium types were incubated in non-haemolytic hypotonic and hypertonic media for 4-5 h at 30 degrees. After initial swelling or shrinking, they readjusted their volume toward their initial isotonic volume. The volume regulation was associated with specific changes in cation fluxes. In the swollen cells, efflux of both sodium and potassium was increased and influx of both cations was slightly decreased; the converse was true for the shrunken cells. All four fluxes were changed in a direction that led to return to normal volume. The difference in the response of the two types of sheep erythrocytes to changes of extracellular fluid osmolality resided in the different activity of their cation transport systems. It is concluded that sheep erythrocytes possess some means of regulating their volume in vitro which is linked to cation permeability. The exact nature of the physical mechanisms by which they accomplish this remains to be elucidated.     

The effect of morphine upon DNA methylation in ten regions of the rat brain

Morphine is one of the most effective analgesics in medicine. However, its use is associated with the development of tolerance and dependence. Recent studies demonstrating epigenetic changes in the brain after exposure to opiates have provided insight into mechanisms possibly underlying addiction. In this study, we sought to identify epigenetic changes in ten regions of the rat brain following acute and chronic morphine exposure. We analyzed DNA methylation of six nuclear-encoded genes implicated in brain function (Bdnf, Comt, Il1b, Il6, Nr3c1, and Tnf) and three mitochondrially-encoded genes (Mtco1, Mtco2, and Mtco3), and measured global 5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5?hmC) levels. We observed differential methylation of Bdnf and Il6 in the pons, Nr3c1 in the cerebellum, and Il1b in the hippocampus in response to acute morphine exposure (all P value < 0.05). Chronic exposure was associated with differential methylation of Bdnf and Comt in the pons, Nr3c1 in the hippocampus and Il1b in the medulla oblongata (all P value < 0.05). Global 5mC levels significantly decreased in the superior colliculus following both acute and chronic morphine exposure, and increased in the hypothalamus following chronic exposure. Chronic exposure was also associated with significantly increased global 5hmC levels in the cerebral cortex, hippocampus, and hypothalamus, but significantly decreased in the midbrain. Our results demonstrate, for the first time, highly localized epigenetic changes in the rat brain following acute and chronic morphine exposure. Further work is required to elucidate the potential role of these changes in the formation of tolerance and dependence.     

The cellular localization of malonyl-coenzyme A decarboxylase in rat brain

Malonyl-coenzyme A (CoA) decarboxylase (E.C.4.1.1.9) activity in brain is low but steadily increases after birth. The main physiological role of this mitochondrial enzyme is thought to be the stabilization of malonyl-CoA levels which change very little with brain growth. In an effort to visualize malonyl-CoA decarboxylase by immunocytochemistry, and to determine its developmental changes, the enzyme was purified by an efficient small-scale procedure involving isolation of mitochondria, extraction at high ionic strength, isoelectric focusing, column chromatography, and preparative polyacrylamide gel electrophoresis. The enzyme from brain showed the same apparent molecular weight (160 kDa) and was immunoreactive with antisera raised against malonyl-CoA decarboxylase from liver. Immunocytochemistry revealed early and extensive labeling of hepatocytes in rat liver but only delayed visualization in the brain. Most nerve cells of the cerebral cortex and many microglia were stained but the neurons of the cerebellar cortex did not become reactive. Golgi epithelial cells and their processes, the Bergmann glia, also showed reaction product.     

The effect of the calcium antagonist nimodipine upon local cerebral glucose utilization in the rat brain

The new calcium antagonist Nimodipine has been shown to have more powerful dilator action on cerebral than peripheral vessels. The effect of the drug on cerebral metabolism was studied in conscious rats using the /14C/-2-deoxyglucose quantitative autoradiographic technique. Intravenous injection of Nimodipine, 2 mcg/Kg, determined significant increases in local cerebral glucose utilization that appeared to be homogeneous in magnitude and anatomic distribution throughout the brain. This study raises the question whether Nimodipine affects brain functions by other mechanisms than an increase in cerebral blood flow.     

The effect of catecholamines and prostaglandins upon human and rat erythrocytes

Both human and rat erythrocytes respond to low doses (10⁻¹¹-10⁻⁹ M) of L-isoproterenol and Lepinephrin with an increased degree of hypotonic hemolysis and a decreased rate of filtration through standardized paper filters. The receptors in both cell types have many of the characteristics of β-receptors for catecholamines. However, hormone-receptor interaction in the human cell does not lead to an increase in intracellular cyclic AMP concentration, but in the rat cell, hormone-receptor interaction does lead to a significant increase in cylic AMP content. Thus, catecholamine-β-receptor interaction, at least in the human red cell, leads to a change in red cell properties which are not mediated by adenylate cyclase activation. Likewise, prostaglandin E₂, at 10⁻¹²-10⁻¹⁰ M, causes an increased degree of hypotonic hemolysis and a decreased rate of filtration through standardized paper filters, but it also does not increase the cyclic AMP content of the human erythrocyte but does increase that of the rat erythrocyte. Nevertheless, exogenous cyclic AMP, when added at a concentration of 10⁻⁸ M to washed human erythrocytes, increases the degree of hypotonic hemolysis. Conversely, prostaglandin E₁, at 10⁻¹²-10⁻¹⁰ M, causes a decreased degree of hypotonic hemolysis and an increased rate of filtration through a standard filter. Both prostaglandin E₂ and the catecholamines decrease the size of a rapidly exchangeable calcium pool, and prostaglandin E₁ increases it.     

Metabolism of cellular membrane sulpholipids in the rat brain

1. Metabolism of [(35)S]sulpholipid was studied in rats of different ages after the injection of [(35)S]sulphate. 2. The turnover of sulphatide in brain myelin and subcellular fractions was followed for long periods. 3. A small fraction of adult myelin underwent rapid metabolism, the rest being relatively metabolically stable. 4. Fast turnover of brain microsomal sulphatide during development was related to the process of myelination. 5. Turnover of mitochondrial sulphatide was at a lower rate than that calculated for liver mitochondria. 6. The relevance of the results to the metabolism of the whole membrane is discussed.     

5'-Nucleotidase and adenosine deaminase activity in the rat brain upon prolonged effect of low radiation doses

The effect of combined low radiation doses (0.2-50.8 cGy) on the 5'-nucleotidase and adenosine deaminase activities in the rat hypothalamus, hippocamp and cerebral cortex during 45, 120 and 365 days was examined. It has been shown that the changes in the 5'-nucleotidase activity of the hypothalamus and hippocamp have a phase character. The direction of the changes in enzyme activity of the hypothalamus and hippocamp adenosine forming was dependent on the zone stay period and had the exactly opposite character depending on the early and prolonged stay period in the zone. 5'-nucleotidase activity was changed under the influence of mean and lesser doses with an increase of the zone stay period. No changes in the 5'-nucleotidase activity of the cerebral cortex were noted. No changes in the hypothalamic adenosine deaminase activity of rats that stayed in a zone during 45 days were revealed; under the effect of mean dose during 120 days the activity decreased and also in case of a higher dosage during one year. The adenosine deaminase activity in animal hippocamp decreased in rats only under the influence of the lesser dose, for 45-day period. The decrease in adenosine deaminase activity of the cerebral cortex that was noted under the effect of all the three doses during 45 days, the higher and mean doses during 120 days disappeared in a year.     

Multimodal imaging to explore endogenous fluorescence of fresh and fixed human healthy and tumor brain tissues

To complement a project toward label‐free optical biopsy and enhanced resection which the overall goal is to develop a multimodal nonlinear endomicroscope, this multimodal approach aims to enhance the accuracy in classifying brain tissue into solid tumor, infiltration and normal tissue intraoperatively. Multiple optical measurements based on one‐ and two‐photon spectral and lifetime autofluorescence, including second harmonic generation imaging, were acquired. As a prerequisite, studying the effect of the time of measurement postexcision on tissue's spectral/lifetime fluorescence properties was warranted, so spectral and lifetime fluorescences of fresh brain tissues were measured using a point‐based linear endoscope. Additionally, a comparative study on tissue's optical properties obtained by multimodal nonlinear optical imaging microscope from fresh and fixed tissue was necessary to test whether clinical validation of the nonlinear endomicroscope is feasible by extracting optical signatures from fixed tissue rather than from freshly excised samples. The former is generally chosen for convenience. Results of this study suggest that an hour is necessary postexcision to have consistent fluorescence intensities\lifetimes. The fresh (a,b,c) vs fixed (d,e,f) tissue study indicates that while all optical signals differ after fixation. The characteristic features extracted from one‐ and two‐photon excitation still discriminate normal brain (a,d) cortical tissue, glioblastoma (GBM) (b,e) and metastases (c,f).