Mechanism of the suppression of the spinal pain syndrome by serotonin derivatives

The ability of serotonin derivatives to stimulate cAMP accumulation in isolated nerve terminals and lumbar enlargement of the spinal cord of normal rats was compared. The effect of the compounds on the intensity of spinal pain syndrome was also assessed. It has been established that substitutes injected into NH2-group of serotonin in 5-OH position attenuate the ability to stimulate cAMP accumulation in synaptosomes, with the effect more pronounced with substitutes of larger volume. A certain correlation between the ability of serotonin derivatives to stimulate adenylate cyclase in vivo and in vitro, on the one hand, and their analgetic effect, on the other hand, is suggested.     

Electron microscopic detection of calcium ions at different stages of normal surfactant formation and during body cooling

Histochemical demonstration of calcium ions in the respiratory part of the rabbit lungs has revealed that the greatest amount of the reaction granules is localized in type II alveolocytes. "Calcium packs" have been discovered, on the basis of which osmiophilic laminar bodies are formed. Cooling of the body entails an increase in the number of osmiophilic laminar bodies with calcium oxalate granules in type II alveolocytes.     

Effect of radiation on cell interactions in the phenomenon of non-syngeneic stem cell inactivation. Changes in B-lymphocyte function after irradiation

A study was made of the changes in the mode of interaction between T- and B-lymphocytes of mouse lymph nodes with respect to the phenomenon of inactivation of non-syngeneic haemopoietic stem cells. It was shown that irradiation of B-lymphocytes with doses of 77.4--232.2 mC/kg changes their helper activity into a suppressor activity with regard to T-cell-killers having a low electrophoretic mobility.     

Dialdehyde ATP derivative as an affinity modifier of the Na+,K(+)-ATPase active site

Interaction of Na+,K(+)-ATPase from pig kidney in various conformational states with the dialdehyde analogue of ATP, alpha,alpha-(9-adenyl)-alpha'-D-(hydroxymethyl)diglycolaldehyde triphosphate ester (oATP), has been studied. This interaction leads to an enzyme modification which was shown to be of the affinity type according to the following criteria. 1. oATP can be hydrolyzed by Na+,K(+)-ATPase and prevent inhibition of ATPase activity by gamma-[4-(N-2-chloroethyl-N-methylamino)]benzylamide ATP, indicating that it interacts with Na+,K(+)-ATPase in the enzyme active site. 2. oATP irreversibly inhibits ATP-hydrolyzing activity of Na+,K(+)-ATPase; the extent of inactivation is decreased in the presence of 20 mM ATP and depends on the ion composition of the modification medium. The inhibition and ATP protection are maximal in Na+,Mg2(+)-containing buffer. 3. The value of [14C]oATP incorporation into the alpha subunit is proportional to the degree of enzyme inactivation at low (less than 0.1 mM) concentration of oATP and, on extrapolation to complete inhibition, corresponds to incorporation of 1.05 mol reagent/mol alpha subunit. 4. Tryptic hydrolysis of the isolated oATP-modified alpha subunit and subsequent separation of the peptides revealed only one labelled fragment with a molecular mass of about 10 kDa. Localization of the modified fragment in the alpha-subunit polypeptide chain is discussed. A morpholine-like structure was shown to be formed as a result of the modification.     

Wilson disease: not just a copper disorder. Analysis of a Wilson disease model demonstrates the link between copper and lipid metabolism

Copper is an essential nutrient required for normal growth and development in many organisms. In humans, the disruption of normal copper absorption and excretion is associated with two severe disorders, known as Menkes disease and Wilson disease, respectively. The consequences of insufficient copper supply that is characteristic of Menkes disease have been largely linked to the inactivation of key metabolic enzymes, although other non-enzymatic processes may also be involved. In contrast, the consequences of copper accumulation in Wilson disease have been generally ascribed to copper-induced radical-mediated damage. Recent studies suggest that the cellular response to copper overload, particularly at the early stages of copper accumulation, involves more specific mechanisms and specific pathways. Genetic and metabolic characterization of animal models of Wilson disease has provided new insights into the pre-symptomatic effects of copper that is accumulated in the liver. The studies have uncovered unexpected links between copper metabolism, cell-cycle machinery, and cholesterol biosynthesis. We discuss these new findings along with the earlier reports on dietary effects of copper. Together these experiments suggest a tight link between lipid and copper metabolism and identify several candidate proteins that may mediate the cross-talk between copper status and lipid metabolism.     

Copper specifically regulates intracellular phosphorylation of the Wilson's disease protein, a human copper-transporting ATPase

Copper is a trace element essential for normal cell homeostasis. The major physiological role of copper is to serve as a cofactor to a number of key metabolic enzymes. In humans, genetic defects of copper distribution, such as Wilson's disease, lead to severe pathologies, including neurodegeneration, liver lesions, and behavior abnormalities. Here, we demonstrate that, in addition to its role as a cofactor, copper can regulate important post-translational events such as protein phosphorylation. Specifically, in human cells copper modulates phosphorylation of a key copper transporter, the Wilson's disease protein (WNDP). Copper-induced phosphorylation of WNDP is rapid, specific, and reversible and correlates with the intracellular location of this copper transporter. WNDP is found to have at least two phosphorylation sites, a basal phosphorylation site and a site modified in response to increased copper concentration. Comparative analysis of WNDP, the WNDP pineal isoform, and WNDP C-terminal truncation mutants revealed that the basal phosphorylation site is located in the C-terminal Ser(796)-Tyr(1384) region of WNDP. The copper-induced phosphorylation appears to require the presence of the functional N-terminal domain of this protein. The novel physiological role of copper as a modulator of protein phosphorylation could be central to understanding how copper transport is regulated in mammalian cells.     

Molecular mechanisms of tumor angiogenesis

The maintenance of growth of malignant tumors is closely related with the development of the vascular network supplying the tumor with blood. The vascularization of tumor tissue is similar to physiological angiogenesis, but in tumors it has some specific features. During the last 25 years a vast number of biomolecules have been found and described which are involved in the regulation of tumor angiogenesis. This review considers the action mechanisms and specific features of expression of the main angiogenic growth factors, such as the vascular endothelium growth factor (VEGF), angiopoietins (Ang-1, Ang-2), and the basic fibroblast growth factor (bFGF). The roles of cytokines, growth factors, proteolytic enzymes, and cell adhesion molecules in the regulation of the key steps of blood vessel generation in the tumor are considered. The significance of angiogenesis in the treatment of oncological diseases and possible approaches for inhibition of the regulatory signals of angiogenic factors are discussed.     

Human copper-transporting ATPase ATP7B (the Wilson's disease protein): biochemical properties and regulation

Wilson's disease protein (WNDP) is a product of a gene ATP7B that is mutated in patients with Wilson's disease, a severe genetic disorder with hepatic and neurological manifestations caused by accumulation of copper in the liver and brain. In a cell, WNDP transports copper across various cell membranes using energy of ATP-hydrolysis. Copper regulates WNDP at several levels, modulating its catalytic activity, posttranslational modification, and intracellular localization. This review summarizes recent studies on enzymatic function and copper-dependent regulation of WNDP. Specifically, we describe the molecular architecture and major biochemical properties of WNDP, discuss advantages of the recently developed functional expression of WNDP in insect cells, and summarize the results of the ligand-binding studies and molecular modeling experiments for the ATP-binding domain of WNDP. In addition, we speculate on how copper binding may regulate the activity and intracellular distribution of WNDP, and what role the human copper chaperone Atox1 may play in these processes.     

Vitamin C prevents DNA mutation induced by oxidative stress

The precise role of vitamin C in the prevention of DNA mutations is controversial. Although ascorbic acid has strong antioxidant properties, it also has pro-oxidant effects in the presence of free transition metals. Vitamin C was recently reported to induce the decomposition of lipid hydroperoxides independent of metal interactions, suggesting that it may cause DNA damage. To directly address the role of vitamin C in maintaining genomic integrity we developed a genetic system for quantifying guanine base mutations induced in human cells under oxidative stress. The assay utilized a plasmid construct encoding the cDNA for chloramphenicol acetyl transferase modified to contain an amber stop codon, which was restored to wild type by G to T transversion induced by oxidative stress. The mutation frequency was determined from the number of plasmids containing the wild type chloramphenicol acetyl transferase gene rescued from oxidatively stressed cells. Cells were loaded with vitamin C by exposing them to dehydroascorbic acid, thereby avoiding transition metal-related pro-oxidant effects of ascorbic acid. We found that vitamin C loading resulted in substantially decreased mutations induced by H(2)O(2). Depletion of glutathione led to cytotoxicity and an increase in H(2)O(2)-induced mutation frequency; however, mutation frequency was prominently decreased in depleted cells preloaded with vitamin C. The mutation results correlated with a decrease in total 8-oxo-guanine measured in genomic DNA of cells loaded with vitamin C and oxidatively stressed. These findings directly support the concept that high intracellular concentrations of vitamin C can prevent oxidation-induced mutations in human cells.     

Cytotoxic action of conjugates of alpha-fetoprotein and epidermal growth factor with photoheme, chlorines, and phthalocyanines

Covalently bound conjugates of alpha-fetoprotein (AFP) and epidermal growth factor (EGF) with photoheme (PH), 3-desvinyl-3-formylchlorine p6 (Chl p6), chlorine e6 (Chl e6), aluminum disulfochloride phthalocyanine (PC(Al)), and cobalt octa-4,5-carboxyphthalocyanine (teraphthal, TP(Co)) were synthesized. Their molar ratios were 1:4 for AFP-cytotoxin conjugates (cf. 1:10 for AFP-TP(Co)) and 1:2 for EGF conjugates (cf. 1:1 for EGF-PC(Al)). Dark toxicity of both protein conjugates with PH, chlorines, and PC(Al) was much lower than their phototoxicity. Studies on phototoxicity demonstrated that PC(Al) conjugates with AFP and EGF and also EGF-Chl p6 were the most effective. The cytotoxic activity (CTA) of AFP-PC(Al) and EGF-Chl p6 was 80% and of EGF-PC(Al) 64% higher than the CTA of the free drugs. Conjugates with TP(Co) were much more toxic on their activation with ascorbic acid (AA): in the presence of AA the CTA of AFP-TP(Co) and of EGF-TP(Co) was 19 and 61.1% higher, respectively, than the CTA of the free TP(Co).