Gold nanoparticles disturb nuclear chromatin decondensation in mouse sperm in vitro

The effect of gold nanoparticles on mouse epididymal sperm has been studied using the model system of nuclear chromatin decondensation in vitro. It is shown that the treatment of gametes, preliminary membrane-freed by sodium dodecyl sulfate, in the mediums containing gold nanoparticles (with diameter ∼2.5 nm) in concentrations 1.0 × 10¹⁵ or 0.5 × 10¹⁵ particles/ml and following incubation in dithiothreitol solution (DTT) resulted in failure of chromatin decondensation process and nucleus structure. We conclude that gold nanoparticles possess spermatotoxicity. The mechanism of cytotoxic effect of gold nanoparticles may be related with their interaction with molecules of double-helix DNA. The model system studied in this research is applicable for further investigations of cytotoxic effects of nanoparticles of different origin and made of different metals.     

Analysis of the chlorophyll biosynthetic system in a chlorophyll b-less barley mutant

The chlorophyll b-less barley (Hordeum vulgare L.) mutant chlorina 2807 allelic to the well-known barley mutant chlorina f2 was studied. 5-Aminolevulinic acid at saturating concentration (40 mM) was introduced into postetiolated leaves of the mutant and its wild type, and the protochlorophyllide accumulation in the dark was measured. It was found that the activity of the enzyme system transforming 5-aminolevulinic acid into protochlorophyllide was the same in both types of plants. The activity of esterifying enzymes that catalyze attachment of phytol to chlorophyllide was analyzed by infiltration of exogenous chlorophyllides a and b into etiolated leaves. The reaction was shown to have close rates in the mutant and wild-type plants. In very early stages of greening of etiolated leaves, when the apoproteins of the light-harvesting complexes are not yet formed, appearance of chlorophyll b was clearly recorded in the wild-type plants, while in the mutant chlorina 2807 no indications of chlorophyll b were detected in any stage of greening. On the other hand, in the mutant as well as in the wild type an active reverse conversion of chlorophyll b into chlorophyll a was possible. It is concluded that (a) in the mutant chlorina 2807 the ability of the biosynthetic system to transform 5-aminolevulinic acid to chlorophyll a is fully preserved, (b) in the mutant the enzymes converting chlorophyll a into chlorophyll b are most likely absent or damaged, (c) the conversion of chlorophyll a into chlorophyll b and the reverse conversion of chlorophyll b into chlorophyll a are performed by different enzymes.     

Actual Problems of Physiology of Microorganisms

Physiology of microorganisms is traditionally considered as one of branches of microbiology. Fundamental works in this field, the last of which were written almost 40 years ago, included such issues, as chemical composition, physico-chemical properties, metabolism, respiration, reproduction, and growth of microorganisms. For the last few decades, the main efforts of scientists in these fields were concentrated on decoding molecular-genetic mechanisms underlying functioning of microbial cells. At the same time, the accumulated scientific data in adjacent fields of biological science require insistently the necessity of new understanding and systematization of results of study of processes of vital activity of all species of living organisms, based on general integrative physiological principles. By the present time, it has been convincingly proved that the existence of higher organisms is impossible without constant interaction with the world of microbes and, hence, physiology of human, animals or plants is inextricably connected with physiological processes of their inhabiting microorganisms. In the present work the main actual problems of modern physiology of microorganisms are considered, and the necessity of separation of this branch of knowledge as an autonomous part of physiology is emphasized.