Morphofunctional characteristics of young rowers with increased blood pressure

The morphofunctional characteristics of 47 young athletes (rowers) were studied. Stage I essential hypertension was found in 25.6% of the young athletes and high normal blood pressure (BP) in 8.5% of the athletes. Detailed clinical and functional observation has shown that, in the group of rowers with an elevated BP, the weight of the left ventricle myocardium was increased and the functional reserve was reduced as compared to the group of athletes with a normal BP level.     

Morphofunctional characteristics of the endosteum

Basing on the literature data analysis, modern notions concerning endosteum structure, its connections with the bone and bone marrow are presented. Participation of the endosteum in processes of osteogenesis and resorption, as well as its changes with ageing are discussed.     

Ultrastructural characteristics of the localization of the enzymes of cyclic nucleotide metabolism in the mammalian brain

The enzymes involved in cyclic nucleotide turnover (adenylate cyclase, guanylate cyclase, phosphodiesterase) were located in various regions of the brain, in synaptosomes and isolated synaptic membranes, using electron cytochemical methods. The interaction of the above enzymes in the processes of adrenergic and cholinergic cell reception in the CNS are discussed.     

Molecular characteristics of glutamate receptors in the mammalian brain

Summary The strong excitatory activity of L-glutamic acid on central nervous system neurons is thought to be produced by interaction of this amino acid with specific neuronal plasma membrane receptors. The binding of L-glutamate to these surface receptors brings about an increase in membrane permeability to Na⁺ and Ca²⁺ ions presumably through direct activation of ion channels linked to the membrane receptors. The studies described in this paper represent attempts to define the subcellular distribution and pharmacological properties of the recognition site for L-glutamic acid in brain neuronal preparations, to isolate and explore the molecular characteristics of the receptor recognition site, and, finally, to demonstrate the activation of Na⁺ channels in synaptic membranes following the interaction of glutamate with its receptors.Radioligand binding assays with L-[³H] glutamic acid have been used to demonstrate a relative enrichment of these glutamate recognition sites in isolated synaptic plasma membranes. The specific binding of L-[³H] glutamate to these membrane sites exhibits rapid association and dissociation kinetics and rather complex equilibrium binding kinetics. The glutamate binding macromolecule from synaptic membranes has been solubilized and purified and was shown to be a small molecular weight glycoprotein (M_T 13 000). This protein tends to form aggregates which have higher specific activity at low concentrations of glutamate than the M_T 13 000 protein has. The overall affinity of the purified protein is lower than that of the high affinity sites in the membrane. Nevertheless, the purified protein exhibits pharmacological characteristics very similar to those of the membrane binding sites. On the basis of its pharmacological properties this protein belongs in the category of the physiologic glutamate preferring receptors.By means of differential solubilization of membrane proteins with Na-cholate, it was shown that this recognition site is an intrinsic synaptic membrane protein whose binding activity is enhanced rather than diminished by cholate extraction of the synaptic membranes. The role of membrane constituents in regulating the binding activity of this protein has been explored and a possible modulation of glutamate binding by membrane gangliosides has been demonstrated. Finally, this glutamate binding glycoprotein is a metalloprotein whose activity is dependent on the integrity of its metallic (Fe) center. This is a clear distinguishing characteristic of this protein vis-à-vis the glutamate transport carriers.The presence of functional glutamate receptors in synaptosomes and resealed synaptic plasma membranes has also been documented by the demonstration of glutamate-activated Na⁺ flux across the membrane of these preparations. The bidirectionality, temperature independence, and apparent desensitization of this stimulated flux following exposure to high concentrations of glutamate are properties indicative of a receptor-initiated ion channel activation. It would appear, then, that the synaptic membrane preparations provide a very useful system for the study of both recognition and effector function of the glutamate receptor complex.     

Energy consumption by phospholipid metabolism in mammalian brain

Until recently, brain phospholipid metabolism was thought to consume only 2% of the ATP consumed by the mammalian brain as a whole. In this paper, however, we calculate that 1.4% of total brain ATP consumption is consumed for the de novo synthesis of ether phospholipids and that another 5% is allocated to the phosphatidylinositide cycle. When added to previous estimates that fatty acid recycling within brain phospholipids and maintenance of membrane lipid asymmetries of acidic phospholipids consume, respectively, 5% and 8% of net brain ATP consumption, it appears that phospholipid metabolism can consume up to 20% of net brain ATP consumption. This new estimate is consistent with recent evidence that phospholipids actively participate in brain signaling and membrane remodeling, among other processes.     

New insights on the influence of free d-aspartate metabolism in the mammalian brain during prenatal and postnatal life

Free d-aspartate is abundant in the mammalian embryonic brain. However, following the postnatal onset of the catabolic d-aspartate oxidase (DDO) activity, cerebral d-aspartate levels drastically decrease, remaining constantly low throughout life. d-Aspartate stimulates both glutamatergic NMDA receptors (NMDARs) and metabotropic Glu5 receptors. In rodents, short-term d-aspartate exposure increases spine density and synaptic plasticity, and improves cognition. Conversely, persistently high d-Asp levels produce NMDAR-dependent neurotoxic effects, leading to precocious neuroinflammation and cell death. These pieces of evidence highlight the dichotomous impact of d-aspartate signaling on NMDAR-dependent processes and, in turn, unveil a neuroprotective role for DDO in preventing the detrimental effects of excessive d-aspartate stimulation during aging. Here, we will focus on the in vivo influence of altered d-aspartate metabolism on the modulation of glutamatergic functions and its involvement in translational studies. Finally, preliminary data on the role of embryonic d-aspartate in the mouse brain will also be reviewed.     

Effect of calcium on brain metabolism in vitro

In attempts to distinguish between direct and indirect effects of Ca on brain cell metabolism, respiration, glycolysis, ATP, phosphocreatine, incorporation of [¹⁴C] leucine into protein, and accumulation of⁴⁵Ca was determined in brain slices. Incubation was carried out in normal salt-balanced medium, in high-potassiumor ouabain-containing medium under aerobic and anaerobic conditions. Calcium ions inhibited slightly glycolysis and respiration in normal medium and activated amino acid incorporation into proteins. Levels of ATP and phosphocreatine remained normal. These effects were interpreted as due to a stabilization of plasma membranes by Ca ions to prevent their spontaneous depolarization. Incubation of slices in high-potassium and ouabain media in aerobic conditions in the presence of Ca resulted in activation of respiration and glycolysis, decrease of ATP and phosphocreatine levels, and inhibition of amino acid incorporation into proteins. The disturbances in energy metabolism, caused by the respiration-linked Ca uptake in brain mitochondria and concomitant inhibition of oxidative phosphorylation, may lead to the inhibition of amino acid incorporation into proteins. An increase in Ca levels in the cytoplasm may only be expected in anaerobic conditions during the incubation in high-potassium and ouabain media. This is manifested by a direct inhibition of glycolysis by Ca ions and a drastic decrease of ATP and phosphocreatine in slices. The results suggest that stimulation of aerobic glycolysis and inhibition of anaerobic glycolysis by Ca may explain the unknown mechanism of the so-called reversed Pasteur effect of brain slices incubated in high-potassium media.     

Morphofunctional characteristics of cadmium-induced arterial hypertension

Chronic (12 weeks) peroral administration of cadmium chloride to albino rats in a dose of 2.5 mg/100 g body weight results in arterial hypertension characterized by the increase in systolic blood pressure up to 148 +/- 1.8 mm Hg (vs. 115.4 +/- 1.5 mm Hg in the control animals); the increase in vascular resistance, left ventricular cardiomyocyte hypertrophy, as well as by hypertrophy of arterial walls, the decrease in the ventricular index, the activation of synthesizing function of atrial endocrine cardiomyocytes; enhanced secretion of ANP; a more than two-fold increase in plasma myoglobin concentration, as well as by the development of cadmium-induced nephropathy. In the rehabilitation period (9 weeks) a relatively quick fall in the blood pressure is observed, as well as morphological features of myocardial and renal function recovery, suggesting the nonpersistent nature of cadmium-induced hypertension.     

Heat production and metabolism during the contraction of mammalian skeletal muscle

Methods are described whereby initial processes of muscular contraction may be investigated in a mammalian preparation, the soleus muscle of the rat. Conditions are chosen so that recovery is avoided. An isometric tetanus is investigated and an energy balance sheet is drawn up. It is found that there is more heat evolved than can be accounted for in terms of measured chemical reaction. This discrepancy is discussed with reference to the similar results that have been obtained using frog muscle.     

Morphofunctional characteristics of the hemomicrocirculatory bed of the canine pericardium

The hemomicrocirculatory bed in the canine pericardium is presented by arterioles, precapillaries, capillaries, postcapillaries and venules situating in various connective tissue layers of the pericardium. Certain morphological peculiarities of the structure of the hemomicrocirculatory bed links are revealed in various parts of the pericardium. As demonstrate morphometry data, the diameter of all the vessels of the hemomicrocirculatory bed in various parts of the pericardium has no precise differences. There are some fluctuations in the number of the capillaries per 1 mm2 in various parts of the pericardium. Their number is comparatively greater in the area of the vascular porta (transitional fold), in the left lateral, in the ventral and dorsal parts of the pericardium. In these parts of the pericardium the density of the capillaries is increased, the network is especially dense in the area where the pericardial transitional fold passes into the epicardium. In the pericardial microcirculatory blood bed adaptive mechanisms (glomeruli, arteriolo-venular anastomoses, microsphincters) performing regulation of the organ's blood stream, are widely presented.     

Neural function: metabolism and actions of inositol metabolites in mammalian brain

In the nervous system, a variety of cell types respond to external stimuli through the inositol lipid signalling pathways. The stimulus-coupled sequence of intracellular events has been investigated in a homogeneous model system, the cloned mammalian neural cell line NG115-401L. The neural peptide bradykinin stimulates a rapid production of identified inositol phosphate isomers and an intracellular Ca2+ discharge followed by a persistent plasma membrane influx. The temporal sequence suggests that Ins(1,4,5)P3 or Ins(1,3,4,5)P4 or both may coordinate these events in a neuronal cell, as has been suggested in other cell types. Thapsigargin, an irritant and tumour-promoting plant product, produces calcium transients in the absence of inositol phosphate production, and may provide a new tool for investigating the interactions between inositol phosphates and changes in cellular calcium homeostasis. In the 401L line, high levels of radiolabelled InsP5 and InsP6 have been detected, which has led to the evaluation of their possible occurrence and actions in normal brain. Both InsP5 and InsP6 are produced from a radiolabelled myo-inositol precursor in intact mature brain in a region-specific manner. This suggests that both inositol polyphosphates may be end products of regionally regulated biosynthetic pathways. When microinjected into a nucleus of the brainstem, or iontophoretically applied to the dorsal horn of the spinal cord, both InsP5 and InsP6, but not Ins(1,3,4,5)P4 isomers, appear to be potent neural stimulants. These results suggest that the inositol lipid signalling pathways may generate both intracellular and extracellular signals in brain.