Effect of nitroammofoska on the aldolase activity of the normal hemolymph in the mollusk Planorbarius banaticus and in trematode invasion

The infection of Planorbarius banaticus with sporocysts of Cotylurus cornutus is accompanied by an increase in aldolase activity of molluscs' haemolymph of 1.2 fold. In solutions of nitroammofoska (0.1, 1 and 10 mg/1) the activity of this ferment in infected individuals increases much higher than in non-infected ones. This results in fast carbohydrate expenditures by molluscs, intermediate hosts of trematodes, and their death from exhaustion.     

Structure of Neuroglobin from Cold-Water Sponge Halisarca dujardinii

Molecular Biology - The iron-containing protein neuroglobin (Ngb) involved in the transport of oxygen is generally considered the precursor of all animal globins. In this report, we studied the...     

Defining the catalytic metal ion interactions in the Tetrahymena ribozyme reaction

Divalent metal ions play a crucial role in catalysis by many RNA and protein enzymes that carry out phosphoryl transfer reactions, and defining their interactions with substrates is critical for understanding the mechanism of biological phosphoryl transfer. Although a vast amount of structural work has identified metal ions bound at the active site of many phosphoryl transfer enzymes, the number of functional metal ions and the full complement of their catalytic interactions remain to be defined for any RNA or protein enzyme. Previously, thiophilic metal ion rescue and quantitative functional analyses identified the interactions of three active site metal ions with the 3'- and 2'-substrate atoms of the Tetrahymena group I ribozyme. We have now extended these approaches to probe the metal ion interactions with the nonbridging pro-S(P) oxygen of the reactive phosphoryl group. The results of this study combined with previous mechanistic work provide evidence for a novel assembly of catalytic interactions involving three active site metal ions. One metal ion coordinates the 3'-departing oxygen of the oligonucleotide substrate and the pro-S(P) oxygen of the reactive phosphoryl group; another metal ion coordinates the attacking 3'-oxygen of the guanosine nucleophile; a third metal ion bridges the 2'-hydroxyl of guanosine and the pro-S(P) oxygen of the reactive phosphoryl group. These results for the first time define a complete set of catalytic metal ion/substrate interactions for an RNA or protein enzyme catalyzing phosphoryl transfer.     

Mechanism of phosphatidylinositol-specific phospholipase C: origin of unusually high nonbridging thio effects

Phosphatidylinositol-specific phospholipase C (PI-PLC) has been proposed previously to employ a catalytic mechanism highly reminiscent of that of ribonuclease A (RNase A). Both catalytic sites are comprised of two histidine side chains acting as a general base-general acid pair and a phosphate-activating residue: an arginine in the case of PI-PLC and a lysine in RNase A. Despite these structural similarities, the PI-PLC reaction is slowed 10(5)-fold upon substitution of one of the phosphate nonbridging oxygen atoms with sulfur, whereas a much smaller effect is observed in the analogous RNase A reaction. Here, we report a systematic study of this property in PI-PLC, conducted by means of site-directed chemical modification of a cysteine residue replacing the arginine at position 69. The results show that mutant enzymes featuring bidentate side chains at this position display significantly higher activity, higher thio effects, and greater stereoselectivity than do those with monodentate side chains. The results suggest that the bidentate nature of Arg69 is the origin of the large thio effects and stereoselectivity in PI-PLC. We propose that in addition to binding the phosphate, the function of arginine 69 is to bring the phosphate group and the 2-OH group of inositol into proximity and to induce proper alignment for nucleophilic attack, and possibly to lower the pK(a) of the 2-OH. The results presented here could be important to mechanisms of phosphoryl transfer enzymes in general, suggesting that a major part of thio effects observed in enzymatic phosphoryl transfer reactions can originate from factors other than direct interaction between a side chain and a phosphate group, and caution the use of the absolute magnitude of the thio effect as an indicator of the strength of such interactions.     

Qualitative and quantitative variation of serum proteins in fluorosis patients

Comparison between patients with occupational fluorosis, a group of healthy workers, and a sample from the general population revealed differences in concentrations of some polymorphic serum proteins. These differences depended on phenotypes of patients. TF 1-2, PI 1-2, and HP 2-1 patients exhibited a decreased concentration of transferrin (TF), a decreased concentration of proteinase inhibitor (PI), and an increased concentration of haptoglobin (HP), respectively.     

Induction of Reactive Oxygen Species and Phytoalexins in Onion (Allium cepa) Cell Culture by Biotic Elicitors Derived from the Fungus Botrytis cinerea

Metabolites of a phytopathogenic fungus Botrytis cinerea Pers. were analyzed for the presence of biotic elicitors. Three groups of elicitors competent in inducing defense responses inAllium cepa cells were identified and partly purified. The recognition of the elicitor signal in onion cells was shown to elevate the concentration of reactive oxygen species (ROS), namely, superoxide anion-radical (O₂^{\overset{-}.}) and hydrogen peroxide (₂₂). The intensity of ROS release depended on chemical identity of elicitor and its concentration. The most active ROS production in onion cells was induced by a protein fraction isolated from the medium for fungus culturing. The carbohydrate elicitors extracted from the fungus cytoplasm and cell walls of mycelia were much less effective. The dynamics of ROS generation comprised two stages. The first stage represented fast and low-amplitude changes that peaked in 15 min after the elicitor treatment. The second stage was more durable and extensive; it occurred in 1.5–6 h after the treatment.     

Population-genetic structure of Chuvashia (from data on eight DNA loci in the nuclear genome)

Population-genetic study of indigenous populations representing three ethnic Chuvash group: highland (Cheboksarsk and Morgaush district), lowland (Kanash district) and mid-lowland (Marposad district). Eight polymorphic DNA loci of the nuclear genome (VNTR/PAH, STR/PAH, VNTR/ApoB, VNTR/DAT1, APF, VNTR/eNOS, IVS6aGATT, and KM.19/PstI) were examined in the population of each district. For each of the four population, we estimated the allele and genotype frequency distributions at each polymorphic system, heterozygosities HS and between-population differences FST. In the combined Chuvash sample, HS = 0.464 and FST = 0.006. Loci VNTR(DAT) and VNTR(ApoB) showed highest between-population differentiation (0.009 < or = FST < or = 0.012), and loci IVS6aGATT, APF, VNTR/eNOS, and D7S23 (KM.19), lowest differentiation (0.001 < or = FST < or = 0.003). Analysis of genetic distances revealed somewhat higher genetic similarity between the Cheboksarsk and Morgaush populations belonging to the highland Chuvash group, whereas the highland Chuvash population from the Marposad district, which belong to the mid-lowland group, was more distant from the former populations.     

Heterochromatin protein 1 is involved in control of telomere elongation in Drosophila melanogaster

Telomeres of Drosophila melanogaster contain arrays of the retrotransposon-like elements HeT-A and TART. Their transposition to broken chromosome ends has been implicated in chromosome healing and telomere elongation. We have developed a genetic system which enables the determination of the frequency of telomere elongation events and their mechanism. The frequency differs among lines with different genotypes, suggesting that several genes are in control. Here we show that the Su(var)2-5 gene encoding heterochromatin protein 1 (HP1) is involved in regulation of telomere length. Different Su(var)2-5 mutations in the heterozygous state increase the frequency of HeT-A and TART attachment to the broken chromosome end by more than a hundred times. The attachment occurs through either HeT-A/TART transposition or recombination with other telomeres. Terminal DNA elongation by gene conversion is greatly enhanced by Su(var)2-5 mutations only if the template for DNA synthesis is on the same chromosome but not on the homologous chromosome. The Drosophila lines bearing the Su(var)2-5 mutations maintain extremely long telomeres consisting of HeT-A and TART for many generations. Thus, HP1 plays an important role in the control of telomere elongation in D. melanogaster.     

Seasonal dynamics of long-chain polyunsaturated fatty acids in littoral benthos in the upper Yenisei river

We studied composition and concentrations of fatty acids (FAs) in benthos from pebbly littoral region of the Yenisei River in a sampling site near Krasnoyarsk city (Siberia, Russia) for 1 year from March 2003 to February 2004. Special attention was paid to major long-chain polyunsaturated fatty acids (PUFAs) of the ω3 family: eicosapentaenoic acid (EPA, 20:5ω3) and docosahexaenoic acids (DHA, 22:6ω3). In phytobenthos, which was dominated by diatoms, the annual maxima of EPA and DHA pool occurred in spring and early summer. In zoobenthos, EPA and DHA pool peaked in autumn, due mainly to an increase of the biomass of dominant taxa (gammarids) and to a moderate increase of the PUFA content per body weight. Seasonal peaks of EPA in overwintering insect larvae (chironomids and caddisflies) generally coincided with those of biomass of these larvae, while there was no such trend for amphipods and oligochaetes. In spring and early summer, the main part of ω3 PUFA, 40–97% of total amount, in the littoral region was contained in biomass of producers, i.e., benthic microalgae, and in autumn it was transferred to primary consumers—benthic invertebrates, which contained ∼76–93% of total ω3 PUFAs.