Subthreshold Ξ

Results on the production of the double strange cascade hyperon Ξ^{-} are reported for collisions of p(3.5 GeV)+Nb, studied with the High Acceptance Di-Electron Spectrometer (HADES) at SIS18 at GSI Helmholtzzentrum for Heavy-Ion Research, Darmstadt. For the first time, subthreshold Ξ^{-} production is observed in proton-nucleus interactions. Assuming a Ξ^{-} phase-space distribution similar to that of Λ hyperons, the production probability amounts to P_{Ξ^{-}}=[2.0±0.4(stat)±0.3(norm)±0.6(syst)]×10^{-4} resulting in a Ξ^{-}/(Λ+Σ^{0}) ratio of P_{Ξ^{-}}/P_{Λ+Σ^{0}}=[1.2±0.3(stat)±0.4(syst)]×10^{-2}. Available model predictions are significantly lower than the measured Ξ^{-} yield.

[LIGHT-DEPENDENT SYNTHESIS OF CELL MEMBRANES IN THE Brc-1 MUTANT OF CHLAMYDOMONAS REINHARDTII].

The structural organization of cells of the Brc-1 mutant of the unicellular green algae Chlamydomonas reinhardtii grown in the light and in the dark has been studied. The Brc-1 mutant contains the brc-1 mutation in the nucleus gene LTS3. In the light, all membrane structures in mutant cells form normally and are well developed. In the dark under heterotrophic conditions, the mutant cells grew and divided well, however, all its cell membranes: plasmalemma, tonoplast, mitochondrial membranes, membranes of the nucleus shell and chloroplast, thylakoids, and the membranes of dictiosomes of the Golgi apparatus were not detected. In the dark under heterotrophic conditions, mutant cells well grow and divide. It were shown that a short-term (1-10 min) exposure of Brc-1 mutant cells to light leads to the restoration of all above-mentioned membrane structures. Possible reasons for the alterations of membrane structures are discussed.

[Ultrastructural organization and composition of carotenoids in the eyespot in the mutant Chlamydomonas reinhardtii].

Biogenesis of the ultrastructure of the eyespot in the chloroplasts of unicellular green algae Chlamydomonas reinhardtii has been studied. We have found that the development of the structure of the eyespot correlates with the accumulation of carotenoids. Depending on their accumulation, the eyespots form from 1 to 4 lines of lipid-carotenoid globules. It has been shown that only carotenes are accumulated in the globules of the eyespots. We first have found that the composition of carotenes in the eyespots of the mutants may vary due to the changes in their composition in the membranes of chloroplasts.

[Structural-functional organization of the cells of Brc-1 mutant Chlamydomonas reinhardtii, supplying protoporphyrin IX in the dark].

The structural-functional characteristics of the cells of wild type CC-124 and Brc-1 mutant of the unicellular green algae Chlamydomonas reinhardtii while growing in the dark and light were studied. It has been shown that the cells of the wild type in heterotrophic and mixotrophic growth conditions had a well developed structure and high functional activity due to the ability of the cells to synthesize chlorophyll both in the light and in the dark. The cells of Brc-1 mutant lost their ability to synthesize chlorophyll in the dark and the cells' color was orange due to brc-1 mutation in the nuclear gene LTS3 that regulated the activity of Mg-chelatase enzyme. In the dark the mutant cells accumulated protoporphyrin IX and had a weakly developed structure with low functional activity. It has been ascertained that due to high content of protoporphyrin IX even a short-term exposure of the cells of Brc-1 mutant to the light was accompanied by very strong destructive changes in all the membranes in a cell: plasmalemma, chloroplast, mitochondrion, shells of the nucleus and vacuoles. The reasons of these significant damages of the membrane components and O2-gas exchange in the cells of Brc-1 mutant are discussed.

[Isolation and physiological and biochemical characterization of the Chlamydomonas reinhardtii C-41 mutant, a superproducer of ξ-carotene].

The composition of the carotenes and xanthophylls of Chlamydomonas reinhardtii Dang. C-41, a mutant of a unicellular green alga and a superproducer of ξ-carotene, was studied. The light-harvesting complexes and a complex of the PS-II reaction center were established to be disrupted in the C-41 mutant. However, the mutant retained a high (up to 46%) photosynthetic activity and the capacity to accumulate chlorophylls and carotenoids (up to 50%). The composition of carotenes was studied, and it was shown that, in contrast to wild-type K(+) cells, which accumulate up to 95% of ß13-carotene and 5% α-carotene, cells of the C-41 mutant contained 43% ß13-carotene, 19% ß3-zeacarotene, and 38% ξ-carotene. The high level of C-41 mutant biomass accumulation made it possible to recommend the mutant as a superproducer of ξ-carotene in phytobiotechnology.

[Disturbed structure and function of chloroplasts during blocked biosynthesis of 5'-aminolevulinic acid in the light].

Xantha-702 mutant of cotton (Gossypium hirsutum L.) proved to have blocked synthesis of 5'-aminolevulinic acid in the light. Accordingly, mutant leaves accumulated 2-5% chlorophyll of baseline. Mutant plants demonstrated disturbed production of pigment-protein complexes of photosystems I (PSI) and II (PSII) and generation of the chloroplast membrane system blocked at the early stages, largely, at the stages of vesicles and single short thylakoid. The functional activity of the PSI and PSII reaction centers was close to zero. Only the chlorophyll a/b light-harvesting complexes of PSI and PSII with the chlorophyll fluorescence peaks at 728 and 681 nm, respectively, were produced in the xantha-702 mutant. We propose that the genetic block of 5-aminolevunilic acid biosynthesis in the light in the xantha-702 mutant disturbs the formation and activity of the complexes of the reaction centers of PS-I and PS-II and inhibits the development of the whole membrane system of chloroplasts.

[Structural-functional organization of chloroplasts in leaves of xantha-702 mutant of Gossypium hirsutum L].

For cotton mutant xantha (Gossypium hirsutum L.), it has been established that synthesis of 5-aminolevulinic acid was blocked in the light. In the light this mutant accumulates chlorophyll by 30 times lower as compared to the parent type. In mutant xantha, a very few pigment-protein complexes of PS-I and PS-II are formed in chloroplasts, and formation of membrane system in these is blocked at the early stages, in most cases, at the stage of bubbles and single short thylakoids. Functional activity of reaction centers of PS-I and PS-II is close to zero. Only light-harvesting chlorophyll-a/b protein complexes of the two photosystems are formed in mutant xantha plastid membranes with maximum chlorophyll fluorescence at 728 and 681 nm, respectively. It has been concluded that in mutant xantha genetic block of 5-aminolevulinic acid biosynthesis in the light disturbs the formation and functioning of the complexes of reaction centers of PS-I and PS-II, hindering the development of the whole membrane system in chloroplasts, causing a sharp decrease in productivity.

[Spectral characteristics and the structure of chloroplasts upon blocking the early stages of chlorophyll biosynthesis].

The cotton mutant xantha (Gossypium hirsutum L.) with the blocked synthesis of 5-aminolevulinic acid in the light has been shown to accumulate chlorophyll 30 times less than the parent type. In chloroplasts of the mutant xantha, the formation of the membrane system is blocked at the earliest stages, mainly at the stage of bubbles and single short thylakoids. Only light-harvesting chlorophyll-a/b-protein complexes I and II with chlorophyll fluorescence maxima at 728 and 681 nm, respectively, are formed in plastid membranes of the mutant. It has been concluded that the genetic block of chlorophyll biosynthesis in the mutant xantha disturbs the formation and functioning of the complexes in reaction centers of PS-I and PS-II, inhibiting the development of the whole membrane system of chloroplasts at the stage of bubbles and single thylakoids.

[The current concepts of functional role of carotenoids in the eukaryotic chloroplasts].

Current state of knowledge of functional role of carotenoids in algal and higher plant chloroplasts is reviewed. Basic functions of carotenoids are shown to be light-protective, light-absorbing, and structural, as well as participating in photochemical processes of photosystems I and II. Such xanthophylls as neoxanthin, fucoxanthin, peridinin and alloxanthin, which have allenic or acetylenic bond, mostly function as light-absorbers. They transmit absorbed energy to chlorophyll b. Other xanthophylls occupying certain strictly specified loci in light-absorbing chlorophyll-a/b-protein complexes of photosystems have either structural function (lutein) or light-protective function (zeaxanthin, antheraxanthin, violaxanthin). Carotenoids of xanthophyll cycles preserve chlorophylls and lipids of photosynthetic membranes from photodestruction at overlighting in the presence of oxygen. In eukaryotic chloroplasts, three types of xanthophyll cycles were found: violaxanthin, lutein-5,6-epoxide, and diadinoxanthin. The similarities and dissimilarities between epoxidation and de-epoxidation reactions of these cycles are discussed in detail in the present work. The pattern of occurrence of xanthophyll cycles among higher plants and freshwater and marine algae is outlined.

[Photochemical activity, spectral properties, and structure of chloroplasts in leaves of Pisum sativum L. under iron deficit and root anaerobiosis].

A combined effect of iron deficit and root anaerobiosis on the biochemical composition, functional activity, and structure of chloroplasts in pea leaves was studied. These factors are shown to affect the chlorophyll accumulation, causing leaf chlorosis. Iron deficit makes itself evident in the chlorosis of top leaves. In the case of root anaerobiosis, chlorosis damages lower plant layers. The destructive effects are summarized under the influence of both factors. The light-harvesting complexes of photosystems are reduced to a greater degree under iron deficit; under root anaerobiosis, complexes of reaction centers of photosystem I and II are reduced. Nevertheless, even under the combined effect of these factors, all pigment-protein complexes and their functional activities are preserved in yellow leaves. The ultrastructure of chloroplasts is gradually reduced in the course of developing chlorosis. In the begging, intergranal sites of thylakoids are destroyed, which is typical for iron deficit, then granal sites are broken. However, even in yellow and almost white leaves, small thylakoids capable of forming stacking and small grana of 2-3 thylakoids are preserved. The destructive effects are summarized due to different mechanisms of action of iron deficit and root anaerobiosis on the structure and function of leaves under their combined effect.

[Time course of the content of folates and free amino acids in leaves of Pisum sativum L. after irradiation with ultraviolet C].

The effect of irradiation with UV-C on the time course of the content of total folates and free amino acids in leaves of pea (Pisum sativum L.) cultivar Neistoshchimyi was studied. It was shown that photolysis of folates is a rapid response to exposure to ultraviolet, as a result of which the plant produces a stable compound, pterin-6-carboxylic acid, with a relative fluorescence quantum yield approximately 2.0 at 20 degrees C (total value, 0.58). Presumably, this compound may be involved in the pterin-mediated photosensitization of singlet oxygen production. The kinetics of changes in the composition of free amino acids after exposure to UV-C has been studied. Exposure to UV-C for 0.5 and 1min induced utilization of free amino acids, suggesting activation of the synthesis of hormones and alkaloids that may facilitate resistance to the stressor. Greater doses as a result of exposure to radiation for 10 and 40 min decreased the content of free hydrophobic amino acids. This phenomenon could be due to the formation of covalent cross-links in membranes, which decrease the accessibility of hydrophobic amino acids. It is concluded that the changes in the qualitative and quantitative composition of free amino acids in leaves of irradiated plants were due to glycolysis.

[Ultrastructure of the plastids of 3 types of Chlamydomonas reinhardi mutants phenotypically yellow in the light or in darkness]. / Ul'trastruktura plastid trekh tipov mutantov Chlamydomonas reinhardi, fenotipicheski zheltykh na svetu ili v temnote

A study was made of the ultrastructure of plastids of three mutant types of Chlamydomonas reinhardi which are phenotypically revealed either in the light or in the darkness as yellow mutants. Characteristics of pigments for each mutant have been given. Mutant Y-4 unable to synthesize chlorophyll either in the light or in the darkness shows a complete reduction of photosynthesizing membranes. Mutant Y-1 capable of synthesizing chlorophyll develops a normal system of photosynthesizing membranes. The dark synthesis of chlorophyll in this mutant is broken, the mutant accumulates only carotenoids, the membrane system of its plastid being reduced. On the contrary, mutant Y-3 has in the darkness a complete set of pigments and a well developed membrane system. In the light this mutant yellows due to chlorophyll photodestruction that is followed by destruction of the membrane system of chloroplasts.

[Transformation of Chlamydomonas reinhardtii CW-15 with the hygromycin phosphotransferase gene as a selective marker]. / Transformatsiia CW-15 Chlamydomonas reinhardtii s ispol'zovaniem gena gigromitsinfosfotransferazy v kachestve selektivnogo markera.

To transform Chlamydomonas reinhardtii Dang. Cells, plasmid pCTVHyg was constructed with the use of the Escherichia coli hygromycin phosphotransferase gene (hpt) controlled by the SV40 early promoter. Cells of the CW-15 mutant strain were transformed by electroporation, with the yield reaching 10(3) hygromycin-resistant (HygR) clones per 10(6) recipient cells. The exogenous DNA integrated in the Ch. reinhardtii nuclear genome showed stable transmission for approximately 350 cell generations, while hygromycin resistance was expressed as an unstable character. Codon usage was compared for the hpt gene and Ch. reinhardtii nuclear genes. The results testified that codon usage bias, which is characteristic of Ch. reinhardtii, is not the major factor affecting foreign gene expression. The advantages of the selective system for studying Ch. reinhardtii transformation with heterologous genes are discussed.

[Structural and functional organization of chloroplasts in leaves of Pisum sativum L. under conditions of root hypoxia and iron deficiency]. / Strukturno-funktsional'naia organizatsiia khloroplastov v list'iakh Pisum sativum L. v usloviiakh kornevoi gipoksii i defitsita zheleza.

A combined effect of iron deficiency and root hypoxia on the biochemical composition activity and structure of chloroplasts in pea leaves have been studied. Both factors are shown to affect the accumulation of chlorophyll causing leaf chlorosis. At iron deficiency chlorosis occurs from the top of plant leaves. At root hypoxia chlorosis starts from the lower strata. At a combined action of both factors the destructive effects are summarized. It was established that light-harvesting complexes of photosystems were reduced stronger at iron deficiency, while complexes of reaction centers of photosystem I and photosystem II are lessened at root hypoxia. Nevertheless, even at a combined effect of both factors yellow leaves preserved small amounts of any pigment-protein complexes and their functional activities. The ultrastructure of chloroplasts during leaf chlorosis was gradually reduced. At first, intergranal sites of thylakoids and then granal ones were destroyed, that was typical of iron deficiency. However, even yellow and almost white leaves kept small thylakoids, capable of forming stacking and small grana made of 2-3 thylakoids. It has been concluded that the destructive effects are summarized due to different kinds of action of iron deficiency and root hypoxia on the structure and functioning of leaves at their combined action.

[The influence of ammonium and nitrate of nutrient medium on ultrastructural organization and photosynthesis of callus cells in Glycine max L]. / Vliianie ammoniia i nitrata pitatel'noi sredy na ul'trastrukturnuiu organizatsiiu i fotosintez kletok kallusa Glycine max L.

We studied the influence of exogenic ammonium on the functional activity and ultrastructural organization of cells of the mixotrophic soybean callus (Glycine max L.). Ammonium available in the nutrient medium increased the chlorophyll content, accelerating the rate of photosynthetic O2 evolution per unit of biomass. The presence of ammonium in the medium promoted formation of the protein-synthesizing system, which manifested itself as increased numbers of ribosomes, and thylakoids of chloroplasts, and higher electron density of the stroma in mitochondria and cytoplasm of mixotrophic cells. It has been concluded that the use of ammonium may lead to activation of protein synthesis, thus rising photosynthetic activity and favouring formation and development of membrane structures in chloroplasts.

[Variability in chlorophyll accumulation and the structure of the chloroplasts in the daughter strains of the phenotypically yellow mutant Y-4 of Chlamydomonas reinhardi]. / Variabil'nost' v nakoplenii khlorofilla i struktura khloroplastov u dochernikh shtammov fenotipicheski zheltogo mutanta Zh-4 Chlamydomonas reinhardi.

The analysis of a group of recombinant strains of phenotypically yellow mutant Y-4 Chlamydomonas reinhardii has shown a considerable variability in displaying the degree of pigmentation. Chlorophyll "a" is the first to accumulate in chloroplasts. Chlorophyll "b" was found in strains when the content of chlorophyll "a" reached 1% of its concentration in cells of the wild type, The occurrence of spectral forms of chlorophyll "a" at 661, 667, 678, 685, 698 and 703 does not correlate with its quantitative accumulation. Variability in pigment accumulation is accompanied by changes both in the structural organization of the membrane system of chloroplasts and in the functional activity of photosystems. The degree of development of chloroplast structure in the group of recombinant strains varies from the formation of vesicules to well developed tilakoids and their arrangement in grains.

[Ultrastructure organization of chloroplasts in chlorotica mutants of Pisum sativum L]. / Ul'trastrukturnaia organizatsiia khloroplastov chlorotica-mutantov Pisum sativum L.

A study was made of chlorophyll-protein complexes of photosystems, and of ultrastructural organization of chloroplasts in pea leaves of the primary cultivar Torsdag and of its mutants, chlorotica 2004 and 2014. It has been shown that mutants accumulated 80 and 55% chlorophyll, respectively, and were able to synthesize all four types of photosystem complexes. The value of the light-harvesting antenna in mutant 2014 was close to the control one, and in mutant 2004 it increased significantly (by 30%). These changes were caused by a proportional decrease (40-50%) in any complexes in mutant 2014, whereas the number of PS-I reaction centre complexes, decreased by 50% in mutant 2004 at nearly complete storage of PS-I reaction centre complexes, decreased by 50% in mutant 2004 at nearly complete storage of PS-II complexes. The proportional decrease of PS-I and PS-II complexes in mutant chlorotica 2014 was followed by partial reduction of the entire membrane system in chloroplasts, but with a normal development of both granal and intergranal thylakoids. On the contrary, the loss of PS-I reaction centre complexes in mutant chlorotica 2004 leads to reduction of unstacked sites of thylakoids in chloroplasts. It is concluded that this effect may be associated with localization of PS-I complexes mainly in unstacked sites of thylakoids.

[Photosystem reaction centers and structural organization of chloroplasts in chlorotica mutants of Pisum sativum L]. / Reaktsionnye tsentry fotosistem i strukturnaia organizatsiia khloroplastov u chlorotica mutantov Pisum sativum L.

Chlorophyll-protein complexes of photosystems (PS), as well as ultrastructural arrangement of chloroplasts in pea leaves of the primary cultivar Torsdag and mutants chlorotica 2004 and 2014 were studied. It was shown that both mutants accumulated 80 and 55% of chlorophyll, respectively, and were able to synthesize all of four types of photosystems complexes. The value of the light-harvesting antenna in mutant 2014 was close to the control one, and in mutant 2004 it increased significantly (by 30%). These changes were caused by a proportional decrease, 40-50%, of any complexes in mutant 2014, whereas the number of PS I reaction centers in mutant 2004 decreased by 50% and the reaction centers of PS II complexes were almost completely retained. It was established that the proportional decrease of PS I and PS II complexes in mutant chlorotica 2014 was followed by a partial reduction of the entire membrane system in chloroplasts, but with a good development of both granal and intergranal sites of thylakoids. On the contrary, the loss of complexes of PS I reaction centers in mutant chlorotica 2004 led to a reduction of unstacked sites of thylakoids in chloroplasts. It was concluded that the disturbance of the lateral orientation of the membrane system of chloroplasts is associated with the loss of complexes of reaction centers of PS I, which is predominantly localized in unstacked sites of thylakoids.

[Fluorescence, chlorophyll shape and number of photosystem reaction centers I and II in chlorotica mutants of Pisum sativum L]. / Fluorestsentsiia, formy khlorofilla i chislo reaktsionnykh tsentrov fotosistem I i II u chrotica mutantov Pisum sativum L.

The fluorescent and absorbing properties of chloroplasts and pigment-protein complexes isolated by gel electrophoresis from pea leaves of the cultivar Torsdag and the mutants chlorotica 2004 and 2014 were studied. From the absorption and fluorescence spectra of chlorophylls and their 2nd derivatives, the range of their changes in the native state at 23 degrees C and specific maxima of fluorescence and the forms of chlorophyll of individual complexes at -196 degrees C were found. It was found that in mutant chlorotica 2004 the intensity of fluorescence of long-wave band at 745 nm (23 degrees C) and the maximum--at 728 nm (-196 degrees C) belonging to the light-harvesting complex I increased. Nevertheless, the accumulation of the chlorophyll forms in this mutant at 690, 697 and 708 nm, which make an antenna of reaction centers of photosystem (PS) I decreased. No spectral differences from the spectrum of the wild type were found in mutant chlorotica 2014, except for a weakening of interaction between the complexes of PS I and PS II. It was shown by gel electrophoresis that both mutants were capable of synthesizing any chlorophyll-protein complexes. However, the analysis of the photochemical activity of reaction centers of PS I and PS II as well as calculations of the value of the photosynthetic unit and the number of reaction centers of the photosystems enabled us to conclude that the quantity of the reaction centers of PS I in the mutant chlorotica 2004 was 1.7 times lower due to disturbance of mutations in biosynthesis or the formation of the chlorophyll a-protein complex of PS I. No primary effect of mutation of chlorotica 2014 was established. Proportional changes of all parameters in this mutant gave us the ground to consider them as secondary ones, which are caused by a decrease in chlorophyll content by half.

[Spectral forms of the chlorophyll of mutants of Chlamydomonas with inactive photosystems]. / Spektral'nye formy khlorofilla mutantov Chlamydomonas s neaktivnymi fotosistemami.

Investigations of non-photosinthesizing mutants of Chlamydomonas reinhardii with damaged activity of both or one of the photosystems have shown that the chlorophyll a form with the absorption maximum at 685 nm and low temperature fluorescence band at 696 nm is a part of the pigment-protein complex of PS-2. Chlorophyll a forms with absorption maxima at 689, 698 and 703 nm belong to the pigment-protein complex of PS-1. They seem to be responsible for the long-wave band of chlorophyll fluorescence with the maximum at 707--718 nm. Chlorophyll a forms with absorption at 661, 667 and 678 nm and a short-wave fluorescence band at 685--690 nm rank among the pigments of the light-converging complex, as well as chlorophyll b with the absorption maximum at 644 and 649 nm.