Incorporation of Copper Ions into T2/T3 Centers of Two-Domain Laccases

Laccase belongs to the family of copper-containing oxidases. A study was made of the mechanism that sustains the incorporation of copper ions into the T2/T3 centers of recombinant two-domain laccase Streptomyces griseoflavus Ac-993. The occupancy of the T3 center by copper ions was found to increase with an increasing copper content in the culture medium and after dialysis of the protein preparation against a copper sulfate-containing buffer. The T2 center was filled only when overproducer strain cells were grown at a higher copper concentration in the medium. Two-domain laccases were assumed to possess a channel that serves to deliver copper ions to the T3 center during the formation of the three-dimensional laccase conformation and dialysis of the protein preparation. A narrower channel leads to the T2 center in two-domain laccases compared with three-domain ones, rendering the center less accessible for copper atoms. The incorporation of copper ions into the T2 center of two-domain laccases is likely to occur in the course of their biosynthesis or the formation of a functional trimer.     

Structure and Polymorphism of Amyloid and Amyloid-Like Aggregates

Biochemistry (Moscow) - Amyloids are protein aggregates with the cross-β structure. The interest in amyloids is explained, on the one hand, by their role in the development of socially...     

Modification of [PSI +] prion properties by combining amino acid changes in N-terminal domain of Sup35 protein

The prion [PSI ⁺] is an amyloid isoform of the release factor eRF3 encoded by the SUP35 gene in Saccharomyces cerevisiae yeast. Naturally occurring amyloid complexes have been studied for a long time, yet their structural organization is still not well understood. The formation of amyloid forms of the wild-type Sup35 protein (Sup35p) is directed by its N-terminal portion, which forms a superpleated β-sheet structure. We previously constructed five mutants, each of which carried a replacement in two consecutive amino acids, one in each of the oligopeptide repeats (OR) and in the Sup35p N-terminal region. Mutations sup35-M1 (YQ46-47KK) and sup35-M2 (QQ61-62KK) lead to the compete loss of prion conformation. Three other mutants, i.e., sup35-M3 (QQ70-71KK), sup35-M4 (QQ80-81KK), and sup35-M5 (QQ89-90KK), formed functional prions. In the current study, we investigated the contribution of each mutant peptide to the stability of the prion and aggregation properties, and compared the effects of single mutants and combinations of different mutant alleles. Studies were carried out in yeast strains designed to carry single or a combination of different SUP35 alleles. Based on our analysis, we propose a model that clarifies the 3D organization of the β-sheet within the prion. We also provide evidence that sup35-M2 and sup35-M4 mutations change the 3D structure of prion complexes. We propose that the destabilization of prion complexes in these mutants is due to the decreased efficiency of the fragmentation of the prion aggregates by chaperone complexes.     

Apoptosis development pathways in human lymphocytes induced by UV light and reactive oxygen species

We have studied alterations in the structural state of DNA, the level of membrane Fas-receptor expression, functional activity of caspase-3, the concentration of Ca²⁺, p53 and cytochrome c proteins in human lymphocyte cells in the dynamics of apoptosis, induced by UV light (240–390 nm) at doses of 151, 1510, and 3020 J/m² and reactive oxygen species (ROS): superoxide anion radical, hydroxyl radical, hydrogen peroxide, and singlet oxygen. It was established that UV light and ROS induce lymphocyte DNA fragmentation after the incubation of a modified cell for 20 h. It was shown that in 1–5 h after UV light and ROS exposure on lymphocytes, an increase is observed in the level of membrane death Fas-receptors as compared to intact cells. Enhancement was revealed in the functional activity of lymphocyte caspase-3 4 h after the generation of singlet oxygen, hydroxyl radical, and the addition of hydrogen peroxide, as well as 8 and 24 h and 6 and 8 h of UV irradiation of cells at doses of 151 and 1510 J/m², respectively. Using the DNA comet approach, it was revealed that DNA damage (single-stranded breaks) appears approximately 15–20 min after UV irradiation of lymphocytes at doses of 1510 and 3020 J/m² and the addition of hydrogen peroxide at a concentration of 10⁻⁶ mol/L (comets of the C1 type) and reaches its maximum 6 h after cell modification (comets of the C2 and C3 types). Six hours after exposure of lymphocytes to hydrogen peroxide and UV light at doses of 1510 and 3020 J/m², it was established that the p53 level increased in the investigated cells. It was established that under UV light exposure and exogenous generation of reactive oxygen species, the increase in the calcium level in lymphocyte cytoplasm is determined by Ca²⁺ efflux from the intracellular depots as a result of activation of the components of the phosphoinositide information transmission mechanism to a cell. A hypothesis was proposed on the correlation between changes in the calcium level and initiation of programmed cell death in human lymphocytes after UV light and ROS exposure. It was concluded that the lead role is played by receptor-mediated (Fas-dependent) caspase and p53-dependent pathways in the development of lymphocyte apoptosis induced by exposure to UV light at doses of 151 and 1510 J/m² and reactive oxygen metabolites. A scheme is presented which considers possible intracellular events leading to apoptotic death of lymphocytes after UV irradiation.