Changes in blood plasma volume in rats during ontogenesis

The dynamics of blood plasma volume were studied for the first time in rats during ontogenesis. The significance of blood plasma volume is estimated in the transport of physiologically active substances to cells and target organs during development. The blood plasma volume was measured in male and female rats during embryogenesis on day 18 (E18), perinatal development on E21 and day of postnatal development (P3), and postnatal development on P15 and P30. Body mass was determined in the same animals and correlation was estimated between the blood plasma volume and body mass. The plasma volume increased 1.9-fold from E18 to E21, 1.4-fold from E21 to P3, 2.1-fold from P3 to P15, and 3.4-fold from P15 to P30. The body mass increased 5-fold from E18 to E21, 2-fold from E21 to P3, 2.3-fold from P3 to P15, and 3.2-fold from P15 to P30. The ratio of blood plasma to body mass was the highest on E18 (19%) and decreased twice by E21. This index varied from 5.4 to 4.8% during postnatal development. No sex-related differences in these indices were found in rats. The results obtained make it possible to determine the total content of physiologically active substances on the basis of their plasma concentration and, thereby, estimate the efficiency of secretory organs.     

Changes in blood plasma volume in rats during ontogenesis

The dynamics of blood plasma volume were studied for the first time in rats during ontogenesis. The significance of blood plasma volume is estimated in the transport of physiologically active substances to cells and target organs during development. The blood plasma volume was measured in male and female rats during embryogenesis on day 18 (E18), perinatal development on E21 and day 3 of postnatal development (P3), and postnatal development on P15 and P30. Blood plasma volume was measured using Evans Blue dye method. Body mass was determined in the same animals and correlation was estimated between the blood plasma volume and body mass. The plasma volume increased 1.9-fold from E18 to E21, 1.4-fold from E21 to P3, 2.1-fold from P3 to P15, and 3.4-fold from P15 to P30. The body mass increased 5-fold from E18 to E21, 2-fold from E21 to P3, 2.3-fold from P3 to P15, and 3.2-fold from P15 to P30. The ratio of blood plasma to body mass was the highest on E18 (19%) and decreased twice by E21. This index varied from 5.4 to 4.8% during postnatal development. No sex-related differences in these indices were found in rats. The results obtained make it possible to determine the total content of physiologically active substances on the basis of their plasma concentration and, thereby, estimate the efficiency of secretory organs.     

Endocrine functions of brain in adult and developing mammals

The main prerequisite for organism’s viability is the maintenance of the internal environment despite changes in the external environment, which is provided by the neuroendocrine control system. The key unit in this system is hypothalamus exerting endocrine effects on certain peripheral organs and anterior pituitary. Physiologically active substances of neuronal origin enter blood vessels in the neurohemal parts of hypothalamus where no blood-brain barrier exists. In other parts of the adult brain, the arrival of physiologically active substances is blocked by the blood-brain barrier. According to the generally accepted concept, the neuroendocrine system formation in ontogeny starts with the maturation of peripheral endocrine glands, which initially function autonomously and then are controlled by the anterior pituitary. The brain is engaged in neuroendocrine control after its maturation completes, which results in a closed control system typical of adult mammals. Since neurons start to secrete physiologically active substances soon after their formation and long before interneuronal connections are formed, these cells are thought to have an effect on brain development as inducers. Considering that there is no blood-brain barrier during this period, we proposed the hypothesis that the developing brain functions as a multipotent endocrine organ. This means that tens of physiologically active substances arrive from the brain to the systemic circulation and have an endocrine effect on the whole body development. Dopamine, serotonin, and gonadotropin-releasing hormone were selected as marker physiologically active substances of cerebral origin to test this hypothesis. In adult animals, they act as neurotransmitters or neuromodulators transmitting information from neuron to neuron as well as neurohormones arriving from the hypothalamus with portal blood to the anterior pituitary. Perinatal rats—before the blood-brain barrier is formed—proved to have equally high concentration of dopamine, serotonin, and gonadotropin-releasing hormone in the systemic circulation as in the adult portal system. After the brain-blood barrier is formed, the blood concentration of dopamine and gonadotropin-releasing hormone drops to zero, which indirectly confirms their cerebral origin. Moreover, the decrease in the blood concentration of dopamine, serotonin, and gonadotropin-releasing hormone before the brain-blood barrier formation after the microsurgical disruption of neurons that synthesize them or inhibition of dopamine and serotonin synthesis in the brain directly confirm their cerebral origin. Before the blood-brain barrier formation, dopamine, serotonin, gonadotropin-releasing hormone, and likely many other physiologically active substances of cerebral origin can have endocrine effects on peripheral target organs—anterior pituitary, gonads, kidney, heart, blood vessels, and the proper brain. Although the period of brain functioning as an endocrine organ is not long, it is crucial for the body development since physiologically active substances exert irreversible effects on the targets as morphogenetic factors during this period. Thus, the developing brain from the neuron formation to the establishment of the blood-brain barrier functions as a multipotent endocrine organ participating in endocrine control of the whole body development.     

Effect of Influenza Virus Proteins Modulate Hemostasis in vitro and in vivo

We studied the effect of influenza virus proteins—hemagglutinin, neuraminidase, nucleoprotein, and membrane protein—on hemostasis in vitro and in vivo. The results demonstrated that envelope proteins hemagglutinin and neuraminidase enhanced the fibrinolytic and anticoagulant activities of blood plasma and the activity of human tissue plasminogen activator. The membrane protein proved to have the highest activity among the core proteins of influenza virus; in contrast to hemagglutinin and neuraminidase, it inhibited fibrinolysis, increased the coagulant activity of blood plasma, and decreased the activity of human tissue plasminogen activator. The combined action of hemagglutinin and neuraminidase increased the plasma fibrinolytic and anticoagulant activities to a greater extent than the individual action of each agent. The combined action of hemagglutinin and membrane protein also increased the plasma fibrinolytic and anticoagulant activities, although to a lesser extent than the action of hemagglutinin alone. These data indicate that viral proteins are physiologically active and can cause influenza-specific disturbances of hemostasis.     

The level of free radical oxidation products in heart and blood plasma in diabetes mellitus combined with chronic alcohol intoxication

The level of glycemia, contents of free radical oxidation products (thiobarbituric acid reactive substances, oxidatively modified proteins) have been investigated in blood plasma and heart of rats with diabetes mellitus subjected to chronic alcohol intoxication. Preexisting diabetes mellitus had no influence on the effect of chronic alcohol consumption on the blood plasma levels of oxidatively modified proteins, thiobarbituric acid reactive substances and glucose. However, the contents of thiobarbituric acid reactive substances and products of oxidative modification of proteins were significantly higher in hearts of diabetic rats with chronic alcohol intoxication than in diabetic rats without alcohol intoxication or in rats subjected to chronic alcohol treatment. The alcohol-induced hyperactivation of free radical processes found in the heart may have additional damaging effect.     

Effect of blood components on the stability of liposomes

The human blood plasma is studied for its effect on the outlet of different substances from lecithin liposomes. It is shown that in the presence of the whole blood the permeability of liposomal membrane for the low-molecular weight compounds increases sharply. Blood plasma proteins play a key role in this process but the influence of albumin, gamma-globulins, fibrinogen as well as of serum lipases is rather insignificant. An increase in the rate of outlet of substances in the presence of blood plasma depends on their molecular weight and may be explained by the formation of dynamic defects or pores of definite size in the liposomal membrane. The formation of these defects (pores) is supposed to proceed due to insertion of blood plasma proteins into the phospholipid matrix of liposomes.     

Neurotransmitter release

Axon terminals release more than one physiologically active substance. Synaptic messengers may be stored in two different types of vesicles. Small electron-lucent vesicles mainly store classical low molecular weight transmitter substances and the larger electron-dense granules store and release proteins and peptides. Release of the two types of substances underlies different physiological control. Release of messenger molecules from axon terminals is triggered by influx of Ca2+ through voltage sensitive Ca2+ channels and a rise in cytosolic Ca2+ concentrations. Neither the immediate Ca2+ target(s) nor the molecular species involved in synaptic vesicle docking, fusion and retrieval are known. It is, however, likely that steps involved in the molecular cascade of transmitter release include liberation of vesicles from their association with the cytonet and phosphorylation by protein kinase C of proteins which have the ability to alter between membrane bound and cytoplasmic forms and thus facilitate or initiate the molecular interaction between synaptic vesicles and the plasma membrane.     

木犀草素通过调节凝血活性物质及凝血因子含量维持机体血液循环功能的稳定

目的 探讨木犀草素通过调节凝血活性物质及凝血因子含量维持机体血液循环功能的作用机制。 方法 采用试剂盒和试管法测定木犀草素作用后的凝血酶原时间和血浆复钙时间;采用酶联免疫吸附法检测木犀草素对血液凝血活性物质血栓素(TXB2)、纤维酶原激活物抑制剂(PAI 1)、促红细胞生成素(EPO)和凝血因子Ⅶ(FⅦ)、凝血因子Ⅸ(FⅨ)含量的影响;采用PCR法测定木犀草素对凝血因子Ⅶ、Ⅸ的基因表达情况。 结果 木犀草素能缩短凝血酶原时间和血浆复钙时间,与对照组相比,40 mg/kg的木犀草素使凝血酶原时间和血浆复钙时间分别降低62.89%和64.05%(t=8.713 6、6.218 1,均P结论 木犀草素具有维持机体血液循环功能稳定的作用,其作用机制是通过提高凝血活性物质的含量,调节凝血因子的基因表达量,提高凝血因子的含量,以及抑制纤维酶原的激活和增加血液的黏度等多方面综合作用来实现的。     

Morphofunctional state of the stomach in rats with hyposalivation

Hypoptyalism and deficiency of physiologically active saliva substances induced by it cause some essential changes in the morphofunctional state of the stomach mucosa, ultrastructure of the gastrin-producing cells and gastrin quantity in blood that testifies to the disturbance of the neurohumoral stomach regulation.     

Pathological and compensatory processes in the cerebral circulation during blood transfusion shock]

In experiments on dogs the intravenous injection of heterogenous blood resulted in a decrease of total arterial pressure, weakening of the brain blood flow, fall of Po2 and pH in the brain cortex. A simultaneous constriction if inner carotid arteries is depending on direct action on the vascular wall of heterogenous proteins and on a release in it of physiologically active substances, such as serotonin. Fine pial arteries were dilated by the compensatory mechanism that was not associated with a decrease of intravascular and with direct action of hypoxia or acid metabolites on vascular walls. It was proposed that the trigger mechanism of this vasodilatation is hypoxic changes of metabolism in the nervous tissue.     

A new vitamin K-dependent protein. Purification from bovine plasma and preliminary characterization.

Four proteins active in blood coagulation have long been known to require vitamin K for their proper biosynthesis: factors II, VII, IX, and X. This paper describes the purification of a hitherto unrecognized vitamin K-dependent glycoprotein from bovine plasma. The biosynthesis of this protein is interfered with by the vitamin K antagonist Dicoumarol. The molecular weight of the protein is approximately 56,000 and, like factor X, it has two polypeptide chains. The light chain binds Ca2+. Its NH2-terminal amino acid sequence is homologous to the NH2-terminal sequences of the other vitamin K-dependent proteins and it contains vitamin K-dependent gamma-carboxyglutamic acid residues. The biological function of this protein is unknown.     

心包液的活性物质研究进展

心脏及出入心的大血管由内、外两层心包膜所包裹,心包液是位于心包腔内的少量液体,含有1.7%～3.5%的蛋白质,总的蛋白含量低于血浆。近年来研究发现许多心脏病患者的心包液中存在心房利钠素（ANP）、脑钠素（BNP）、内皮素（ET）及金属蛋白酶等活性物质,浓度显著高于血清,而且其水平变化和心功能密切相关。本文就心包液的组成成分及其中的活性物质和心脏疾病及心功能的关系进行了综述。     

Biological tests of physiologically active compounds (approaches): Communication II

This review considers the methods of investigation proposed by L. A. Piruzyan in the field of preclinical trials of physiologically active compounds: (1) the search for new physiologically active compounds illustrated by analysis of the developmental mechanisms of some diseases, such as jaundice of the newborn, renal and liver insufficiency, acute drug-induced intoxication, discoid and systemic lupus erythematosus, and lupus-like syndrome; (2) experimental studies on safety of medicinal substances—the testing of substances for mutagenicity and embryotoxicity, the preparation of compounds with antimutagenic and anticarcinogenic properties, the determination of preserved blood characteristics; (3) the stabilization of medicinal preparations for use—with drug oxidation inhibitors, and substances contained in liposomes. The ligand pathology concept is presented. The necessity of an individualized approach for assessment of chemical compound safety for humans in emphasized: it should be based on the activity determination of certain enzymes in each subject. Deceased.     

Perfluorcarbon nanocontainers with the nitric oxide transfer function

Hydrophobic nanocontainers in the blood channel of the organism promote rapid delivery or removal of some physiologically active compounds. At sites of excess, physiologically active compounds are loaded into nanocontainers and are transferred by the blood flow inside the organism. The realization of such systems is illustrated by an example of oxygen and nitric oxide transfer by perfluorcarbon nanocontainers. The efficiency of the delivery of the physiologically active compounds by means of nanocontainers has been also analyzed.     

Possible relation of prostaglandins to PMN-derived mediators of host metabolic responses to inflammation

Stimulated rabbit peritoneal polymorphonuclear leukocyte (PMN) preparations simultaneously produce prostaglandin-like material and mediators that induce metabolic alterations in experimental animals characteristic of the host's responses to inflammation. The alterations observed in rats include responses by: proteins, carbohydrates, hormones, trace metals, and total blood neutrophils. This study demonstrates a possible relationship between prostaglandins and PMN-derived substances that mediate plasma zinc depression, hepatic amino acid uptake, and increased numbers of blood neutrophils. Production of these mediators by stimulated-PMN preparations was prevented by 23 μM indomethacin or 93 μM aspirin. Conversely, morphine (2 mM or less) had no detrimental effect on production of these mediators, although, it consistently stimulated production of a substance stimulating total blood neutrophilia. In addition, 2 μM prostaglandin E and F stimulated production of substances mediating hepatic amino acid uptake and plasma zinc depression, respectively. At this concentration, neither prostaglandin significantly altered production of substances mediating increased numbers of total blood neutrophils. A partial-nitrogen atmosphere, dibutyryl cyclic analogs of AMP and GMP, or homogenization of the PMN had no effect on mediator production. The inhibitory effect of indomethacin and aspirin also was observed with PMN-homogenates. These experimental observations suggest that prostaglandin synthesis has a function in production of mediators by stimulated-PMN preparations.     

Prohibitin function within mitochondria: essential roles for cell proliferation and cristae morphogenesis

Prohibitins comprise an evolutionary conserved and ubiquitously expressed family of membrane proteins. Various roles in different cellular compartments have been proposed for prohibitin proteins. Recent experiments, however, identify large assemblies of two homologous prohibitin subunits, PHB1 and PHB2, in the inner membrane of mitochondria as the physiologically active structure. Mitochondrial prohibitin complexes control cell proliferation, cristae morphogenesis and the functional integrity of mitochondria. The processing of the dynamin-like GTPase OPA1, a core component of the mitochondrial fusion machinery, has been defined as a key process affected by prohibitins. The molecular mechanism of prohibitin function, however, remained elusive. The ring-like assembly of prohibitins and their sequence similarity with lipid raft-associated SPFH-family members suggests a scaffolding function of prohibitins, which may lead to functional compartmentalization in the inner membrane of mitochondria.     

Genoprotective human blood activity and its mechanisms

Anticlastogenic properties of plasma and proteins (albumin and gamma-globulin) of the human blood were studied using seeds of Crepis capillaris (chromosome aberration assay). Antimutagen p-amino-benzoic acid was used as a comparative reagent. Anticlastogenic activity dependent of processing conditions of the biosubstrate used; for the pre-processing and combined processing anticlastogenic effect was higher than for post-processing, the processing properties of the blood being higher than those of the blood proteins. Anticlastogenic potential of biosubstrates did not depend on mutation inductor. Complex-formimg properties of plasma and blood albumen have been revealed using spectrop-hotometry through the substantial spectral displacement--relative to the expected spectrum--for the mixture of biosubstrata and mutagens. Using chemoluminescence, all plasma, albumin and gamma-globulin concentrations have been shown to enhance generation of hydroxyl radical of the Fenton reagent, especially for albumin in 1.0 g/l concentration. The general trend for all experiments was that the said substances diminished the stimulating effect as their concentrations grew. Peroxidation of yolk lipoproteids showed that only high concentrations of blood's plasma and albumen have antioxidizing properties. gamma-Globulin did not reveal any ability to inhibit lipid peroxidation of yolk lipoproteids. Complex-forming mechanisms of blood's albumen and antioxidizing property of human plasma and proteins have been proved to form the blood's anticlastogenic potential.     

Chemical Features of Medicinal Plants (Review)

Data on chemical composition related to the synthesis of physiologically active substances (alkaloids, terpenoids, glycosides, phenolic compounds, etc.) and to the accumulation of individual elements or groups of five to ten elements (e.g., Cr, Co, Mn, and Zn) in medicinal plants were reviewed. Chemical features of medicinal plants serve as an integral determinant of their species specificity and pharmacological properties and enable their wide use in medical practice. The relationship between the synthesis of physiologically active substances and accumulation of elements is mediated by several levels of molecular regulation.     

Chemistry of medicinal plants (review)]

Data on the chemical composition related to synthesis of physiologically active substances (alkaloids, terpenoids, glycosides, phenolic compounds, etc.), and accumulation of individual elements or groups of five to ten elements (e.g., Cr, Co, Mn, and Zn) in medicinal plants were reviewed. Chemical features of medicinal plants serve as an integral determinant of their species specificity and pharmacological properties and enabling their wide use in medical practice. The relationship between the synthesis of physiologically active substances and accumulation of elements is mediated by several levels of molecular regulation.     

Enzymes of snake venoms

Snakes' venom is a mixture of biologically active substances, containing proteins and peptides. A number of these proteins interact with haemostasis system components. Activators and inhibitors affecting blood coagulation and fibrinolysis systems are of special interest. Venom components can be classified into three main groups, such as procoagulants, anticoagulants and fibrinolytic enzymes according to their action. This review is focused on enzymes from Agkistrodon halys halys venom. They are thrombine-like enzyme, named Ancystron-H, flbrinogenolytic enzyme, protein C activator and platelet aggregation inhibitor. Ancystron-H is used for determination of fibrinogen level in blood plasma of patients undergoing heparin treatment and blood coagulation inhibitors accumulation. The fibrinogenolytic enzyme can be used as the instrument for protein-protein interactions in fibrinogen-fibrin system. The protein C activator is used for protein C level determination in blood plasma with different pathologies. Functions of the platelet aggregation inhibitor, belonging to disintegrins group, can be used for development of antithrombotic preparations. Information about the use of snake venoms in science and medicine is presented.