Cytokine polymorphisms in silicosis and other pneumoconioses

Silicosis and coal workers' pneumoconiosis are complex multifactorial lung diseases whose etiopathogenesis are not well defined. It is generally accepted that fibrotic lung disorders are mediated by macrophage-derived cytokines and growth factors. There is evidence showing a crucial role for tumor necrosis factor- (TNF-) and interleukin-1 (IL-1) in inflammation caused by silica dust and in the transition from simple to progressive massive fibrosis. In this review we discuss genetic polymorphisms responsible for regulating the production of these proinflammatory cytokines and their role in modifying silicosis severity.     

Synthesis and biological study of new galanthamine-peptide derivatives designed for prevention and treatment of Alzheimer’s disease

Amino Acids - The Alzheimer’s disease leads to neurodegenerative processes and affecting negatively million people worldwide. The treatment of the disease is still difficult and incomplete in...     

Combining tree-ring analyses on stems and coarse roots to study the growth dynamics of forest trees: a case study on Norway spruce (Picea abies [L.] H. Karst)

We show the potential of a new method combining tree-ring analyses on stems and on coarse roots of individual trees in order to advance the understanding of growth dynamics in forest trees. To this end, we studied the root–shoot allometry of trees and its dependence on site conditions. Along a gradient in water supply in Southern Germany from dry to moist sites we selected 43 Norway spruce trees (Picea abies [L.] H. Karst.) aged 65–100 years. Increment cores were taken from stem and main roots revealing aboveground and belowground growth course over the last 34 years. Annual growth rates in roots and stems and their allometric relationships were applied as surrogate variables for tree resource allocation to aboveground and belowground organs. The mean sensitivities of both stem and root chronologies were found to be site-specific, and increased from the moist through the dry sites. No temporal offset between aboveground and belowground growth reactions to climate conditions was found in Norway spruce at any of the sites. These results suggest that the root–shoot allometry depends on the specific site conditions only at the driest site, following the optimal biomass partitioning theory (the more restricted the water supply, the more organic matter allocation into the belowground organs).     

Structure of hemocyanin subunit CaeSS2 of the crustacean Mediterranean crab Carcinus aestuarii

Arthropodan hemocyanins are giant respiratory proteins responsible for oxygen transport. They exhibit unusual assemblies of up to 48 structural subunits. Hemocyanin from Carcinus aestuarii contains three major and two minor structural subunits. Here, we reveal the primary structure of the gamma-type 75 kDa subunit of Carcinus aestuarii hemocyanin, CaeSS2, and combine structure-based sequence alignments, tryptophan fluorescence, and glycosylation analyses to provide insights into the structural and functional organisation of CaeSS2. We identify three functional domains and three conserved histidine residues that most likely participate in the formation of the copper active site in domain 2. Oxygen-binding ability of Carcinus aestuarii Hc and its structural subunit 2 was studied using CD and fluorescence spectroscopy. Removing the copper dioxygen system from the active site led to a decrease of the melting temperature, which can be explained by a stabilizing effect of the binding metal ion. To study the quenching effect of the active site copper ions in hemocyanins, the copper complex Cu(II)(PuPhPy)2+ was used, which appears as a very strong quencher of the tryptophan emission. Furthermore, the structural localization was clarified and found to explain the observed fluorescence behavior of the protein. Sugar analysis reveals that CaeSS2 is glycosylated, and oligosaccharide chains connected to three O-glycosylated and one N-glycosylated sites were found.     

Light-dependent reversal of dark-chilling induced changes in chloroplast structure and arrangement of chlorophyll-protein complexes in bean thylakoid membranes

Changes in chloroplast structure and rearrangement of chlorophyll-protein (CP) complexes were investigated in detached leaves of bean (Phaseolus vulgaris L. cv. Eureka), a chilling-sensitive plant, during 5-day dark-chilling at 1 degrees C and subsequent 3-h photoactivation under white light (200 mumol photons m(-2) s(-1)) at 22 degrees C. Although, no change in chlorophyll (Chl) content and Chl a/b ratio in all samples was observed, overall fluorescence intensity of fluorescence emission and excitation spectra of thylakoid membranes isolated from dark-chilled leaves decreased to about 50%, and remained after photoactivation at 70% of that of the control sample. Concomitantly, the ratio between fluorescence intensities of PSI and PSII (F736/F681) at 120 K increased 1.5-fold upon chilling, and was fully reversed after photoactivation. Moreover, chilling stress seems to induce a decrease of the relative contribution of LHCII fluorescence to the thylakoid emission spectra at 120 K, and an increase of that from LHCI and PSI, correlated with a decrease of stability of LHCI-PSI and LHCII trimers, shown by mild-denaturing electrophoresis. These effects were reversed to a large extent after photoactivation, with the exception of LHCII, which remained partly in the aggregated form. In view of these data, it is likely that dark-chilling stress induces partial disassembly of CP complexes, not completely restorable upon photoactivation. These data are further supported by confocal laser scanning fluorescence microscopy, which showed that regular grana arrangement observed in chloroplasts isolated from control leaves was destroyed by dark-chilling stress, and was partially reconstructed after photoactivation. In line with this, Chl a fluorescence spectra of leaf discs demonstrated that dark-chilling caused a decrease of the quantum yield PSII photochemistry (F(v)/F(m)) by almost 40% in 5 days. Complete restoration of the photochemical activity of PSII required 9 h post-chilling photoactivation, while only 3 h were needed to reconstruct thylakoid membrane organization and chloroplast structure. The latter demonstrated that the long-term dark-chilled bean leaves started to suffer from photoinhibition after transfer to moderate irradiance and temperature conditions, delaying the recovery of PSII photochemistry, independently of photo-induced reconstruction of PSII complexes.     

Identification and Heterologous Expression of Genes Involved in Anaerobic Dissimilatory Phosphite Oxidation by Desulfotignum phosphitoxidans

Desulfotignum phosphitoxidans is a strictly anaerobic, Gram-negative bacterium that utilizes phosphite as the sole electron source for homoacetogenic CO₂ reduction or sulfate reduction. A genomic library of D. phosphitoxidans, constructed using the fosmid vector pJK050, was screened for clones harboring the genes involved in phosphite oxidation via PCR using primers developed based on the amino acid sequences of phosphite-induced proteins. Sequence analysis of two positive clones revealed a putative operon of seven genes predicted to be involved in phosphite oxidation. Four of these genes (ptxD-ptdFCG) were cloned and heterologously expressed in Desulfotignum balticum, a related strain that cannot use phosphite as either an electron donor or as a phosphorus source. The ptxD-ptdFCG gene cluster was sufficient to confer phosphite uptake and oxidation ability to the D. balticum host strain but did not allow use of phosphite as an electron donor for chemolithotrophic growth. Phosphite oxidation activity was measured in cell extracts of D. balticum transconjugants, suggesting that all genes required for phosphite oxidation were cloned. Genes of the phosphite gene cluster were assigned putative functions on the basis of sequence analysis and enzyme assays.Phosphorus (P) is an important nutrient for all living organisms. The predominant forms of phosphorus in biological systems are inorganic phosphate and its organic esters and acid anhydrides in which P is at its highest oxidation state (+V). The P requirements of living cells can be fulfilled with phosphate in various forms, including reduced organic and inorganic phosphorus compounds (23). Several aerobic bacteria were shown to be able to oxidize hypophosphite (+I) and phosphite (+III) to phosphate (+V) and to incorporate the last into their biomass (5, 15-17, 31, 34). Phosphite can also be oxidized under anaerobic conditions, as shown for an anaerobic Bacillus strain (7) and for Pseudomonas stutzeri which can use phosphite under denitrifying conditions (17, 21). The only bacterium known to oxidize phosphite as the sole source of electrons in lithoautotrophic energy metabolism is Desulfotignum phosphitoxidans (24, 25).Three different metabolic pathways for the use of phosphite as a single P source have been characterized so far. Two of them were discovered and characterized with Escherichia coli and one with Pseudomonas stutzeri. The first pathway in E. coli is mediated by the enzyme carbon phosphorus lyase (C-P lyase), and the second one by the alkaline phosphatase encoded by phoA (16, 34). This alkaline phosphatase not only hydrolyzes phosphate esters but also hydrolyzes phosphite to phosphate and molecular hydrogen (32). This is a particular property only of the E. coli alkaline phosphatase and is not observed with alkaline phosphatases of other bacteria. The third pathway is encoded by the ptxABCDE gene cluster in P. stutzeri (17). In this system, phosphite is transported into the cell by a binding protein-dependent phosphite transporter at the expense of ATP (PtxABC). Phosphite is oxidized by a phosphite:NAD⁺ oxidoreductase (encoded by ptxD), a new member of the 2-hydroxy acid dehydrogenases (8). The ptx operon of P. stutzeri is regulated in response to phosphate starvation by the two-component regulatory system phoBR (28, 29). Furthermore, in Alcaligenes faecalis WM2072, another gene cluster involved in hypophosphite and phosphite uptake and oxidation was characterized: the htxABCD-ptxDE locus (31). The htxABCD-ptxDE genes and their products in A. faecalis WM 2072 have high nucleotide and amino acid sequence identities with those found in the htx and ptx operons in P. stutzeri WM88, which are required for the oxidation of hypophosphite and phosphite, respectively. This unique genetic arrangement of hypophosphite- and phosphite-oxidizing genes in A. faecalis WM2072 suggests a horizontal gene transfer and an ancient evolution of phosphite oxidation.The diversity of pathways used for assimilatory phosphite oxidation and the fact that D. phosphitoxidans is so far the only bacterium known to use phosphite as an electron source caused us to investigate the phosphite uptake and oxidation gene cluster of this bacterium. The aims of our study were (i) to establish enzymatic assays for measurement of phosphite oxidation activity in cell extracts, (ii) to identify the genes involved in phosphite uptake and oxidation, and (iii) to characterize these genes physiologically.     

Effect of copper ions on the ligninolytic enzyme complex and the antioxidant enzyme activity in the white-rot fungus Trametes trogii 46

White-rot fungi of the Phylum Basidiomycota are quite promising in ligninolytic enzyme production and the optimization of their synthesis is of particular significance. The aim of this study was to investigate the effect of enhanced concentration of copper (Cu) ions (25–1000 μg/ml) on the activity of the ligninolytic enzyme complex (laccase, Lac; lignin peroxidase, LiP; Mn-peroxidase, MnP) in Trametes trogii 4₆, as well as the changes in the antioxidant cell response. All concentrations tested reduced significantly in growth and glucose consumption. Cu ions affected the ligninolytic enzyme activity in a dose dependent manner. Concentrations in the range of 25–100 μg/ml strongly stimulated Lac production (a 5–6-fold increase compared to the control). LiP activity was also induced by Cu, with the peak value being recorded following exposure to 50 μg/ml metal ions. In contrast, the addition of Cu ions had a positive effect on MnP activity at a concentration higher than 100 μg/ml. The maximum enzyme level was achieved at 1000 μg/ml. The results obtained on superoxide dismutase and catalase activities indicated that exposure of T. trogii 4₆ mycelia to Cu ions promoted oxidative stress. Both enzyme activities were co-ordinately produced with Lac and LiP but not co-ordinately with MnP.