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131	Avaliação de parâmetros fisiológicos em cultivares de cana-de-açúcar submetidas ao déficit hídrico Graça, José Perez da [UNESP] 10 February 2009 (has links) (PDF) Made available in DSpace on 2014-06-11T19:26:08Z (GMT). No. of bitstreams: 0 Previous issue date: 2009-02-10Bitstream added on 2014-06-13T20:47:02Z : No. of bitstreams: 1 graca_jp_me_jabo.pdf: 256015 bytes, checksum: 389bd2988baccfc63d2527a482a1e26f (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / A cana-de-açúcar (Saccharum spp.) é uma das principais culturas das regiões tropicais, cuja produtividade agrícola pode ser afetada pelo déficit hídrico. Para investigar o processo de tolerância e sensibilidade ao déficit hídrico, diferentes parâmetros fisiológicos foram avaliados em cultivares de cana-de-açúcar tolerantes (SP83-2847 e CTC15) e sensível (SP86-155) ao déficit hídrico. A deficiência hídrica afetou todo o aparato fotossintético das plantas de forma diferenciada dentro e entre as cultivares. A taxa fotossintética e condutância estomática diminuíram significativamente para todas as cultivares submetidas ao estresse. Nas plantas controle das cultivares (cv) tolerantes SP83-2847 e CTC15 observou-se que a taxa fotossintética apresentou valores mais altos em comparação a cultivar sensível SP86-155. Resultados do teor relativo de água mostraram que a cultivar CTC15 apresentou melhor condição hídrica durante o período de déficit hídrico. A eficiência quântica do fotossistema II da cultivar SP83-2847 mostrou maior estabilidade nos últimos dias do tratamento experimental, sugerindo que o decréscimo do teor relativo de água estimulou o ajuste da capacidade fotossintética frente às alterações da disponibilidade hídrica. De modo geral, as cultivares SP83-2847 e CTC15, consideradas tolerantes, sob déficit hídrico exibiram melhor desempenho em relação a cultivar sensível SP86-155. Os dados permitem sugerir que tais parâmetros fisiológicos podem ser empregados na avaliação e distinção de genótipos de cana-de-açúcar tolerantes e sensíveis ao déficit hídrico. / The sugarcane (Saccharum spp.) is one of the main crops cultivated in tropical areas, whose agricultural productivity can be affected by drought. To investigate the tolerance and sensitivity process to water deficit, various physiological parameters were evaluated in sugarcane cultivars considered tolerant (SP83-2847 and CTC15) and sensitive (SP86-155) to drought. The water deficit affected the entire photosynthetic apparatus of all plants in different manners, inside and among cultivars. The photosynthetic rate and stomatal conductance decreased significantly for all cultivars, submitted to water stress. In control plants of the tolerant cultivars SP83-2847 and CTC15, it was observed that the photosynthetic rate showed better values in comparison to sensitive cultivar SP86-155. According to relative water content results of the cultivar CTC15 showed better condition water performance during the drought. The quantum efficiency photosystem II of the cultivar SP83-2847 showed greater stability in recent days of the experimental treatment, suggesting that the decline in the relative water content stimulated the adjustment of photosynthetic capacity to face the changes in water availability. Thus, cultivars SP83-2847 and CTC15, considered tolerant under water deficit, showed better performance in comparison to sensitive cultivar SP86-155. The data suggest that these physiological parameters can be used in the evaluation and distinction of drought tolerant and sensitive sugarcane genotypes. Cana-de-açúcar Secas Eficiência quântica do fotossistema II Teor relativo de água Saccharum Estresse hídrico Taxa fotossintética Quantum efficiency photosystem II Relative water content Water stress Photosynthetic rate Drought
132	Comportamento de clones de eucalipto em resposta a disponibilidade hídrica e adubação potássica / Mendes, Hélio Sandoval Junqueira. January 2011 (has links) Resumo: O trabalho objetivou avaliar o efeito do suprimento de potássio no desempenho de clones de eucalipto submetidos a duas condições de disponibilidade hídrica em casa de vegetação utilizando características biométricas e fisiológicas. Cinco genótipos de eucalipto foram submetidos a dois níveis de adubação potássica (K0 - sem complementação potássica e K1 - adição de 166 mg.dm-3 de K) e a dois regimes de irrigação (RI1 - irrigação diária, até o solo atingir 60% dos poros preenchidos com água (PPA), ou seja, plantas sem restrição hídrica, e RI2 - plantas irrigadas até o solo atingir 60% PPA, com posterior suspensão da irrigação, até o aparecimento de sintomas iniciais de deficiência hídrica). Foram conduzidos sete ciclos de suspensão de irrigação, sendo a quantidade de água reposta em cada vaso determinada pelo método gravimétrico. No início e ao final do experimento, foram avaliados o diâmetro do coleto, a altura, o número de folhas, a área foliar e a massa de matéria seca de folhas, caule, raízes, da parte aérea e total. Nos momentos de máximo estresse hídrico, foram avaliadas as seguintes características fisiológicas: teor relativo de clorofila total (ICC), medida da eficiência quântica do fotossistema II (Fv/Fm), taxa de assimilação líquida (A), condutância estomática (gs), taxa de transpiração (E), eficiência intrínseca do uso da água (EUAintr=A/E), eficiência instantânea do uso da água (EUAinst=A/gs), conteúdo relativo de água (CRA) e, ao final do experimento foi determinado o potencial hídrico foliar ( f). O experimento foi estabelecido no delineamento de blocos ao acaso, em esquema fatorial 5 x 2 x 2 (5 genótipos, 2 regimes de irrigação e 2 níveis de adubação potássica), com cinco repetições por tratamento. As médias de tratamentos foram comparadas pelo teste de Tukey a 5% de probabilidade... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: The present study aimed to evaluate the supply potassium effect on the performance of the five eucalypt clones subjected to two water availability conditions in greenhouse from biometric and physiological traits. Five eucalypt genotypes were subjected to two levels of potassium supply (K0 - no potassium supplementation and K1 - addition of 166 mg dm-3 K) and two irrigation regimes (RI1- daily irrigation until the soil reaches 60% of pores filled with water (PFW), that is plants no water restriction, and RI2 - plants watered until the soil reaches 60% (PFW), with subsequent water suspension until the appearance of early water stress symptoms). Seven cycles of irrigation suspension were conducted, and the amount water replaced in each pot was determined by gravimetric method. At the beginning and the end of the experiment, were measured the collar diameter, height, leaf number, leaf area and dry weight mass of leaves, stems, roots, aerial parts and total. In the moment of maximum water stress were evaluated the following physiological traits: the chlorophyll content index (CCI), the quantum efficiency of photosystem II (Fv/Fm), net assimilation rate (A), stomatal conductance (gs), transpiration (E), intrinsic water use efficiency (WUEintr = A/E) and instantaneous water use efficiency (WUEinst = A/gs), relative water content (RWC) and at the end of the experiment was determined the leaf water potential ( f). The design experiment was established in the randomized blocks in factorial scheme 5 x 2 x 2 (5 genotypes, two irrigation regimes and two levels of potassium supplies), with five replicates. The treatment means were compared by Tukey test at 5% probability. Eucalypt clones present reduction in the biometric and physiological traits values under water limitations. For the physiological traits, the potassium supply caused effect reduction of the water stress. To the biometric... (Complete abstract click electronic access below) / Orientador: Rinaldo Cesar de Paula / Coorientadora: Nádia Figueiredo de Paula / Banca: Mara Cristina Pessôa da Cruz / Banca: Miguel Luiz Menezes Freitas / Mestre Plantas - Nutrição. Eucalipto. Biological control. eng Drought. eng Choropyll content. eng Plant nutrition. eng Forest tree improvement. eng Photosystem II. eng
133	Studium interakce membránových proteinů na molekulární úrovni pomocí silové spektroskopie, optické spektroskopie a metod výpočetní biochemie / Membrane protein interactions studied on single molecular level by force spectroscopy, optical spectroscopy and methods of computational biochemistry MATĚNOVÁ, Martina January 2011 (has links) I have set for a challenging study that combined experimental and theoretical approaches in an attempt to resolve a role of small aminoacids in intermolecular interactions. First, I have proposed a hypothesis that described the interaction among individual aminoacids forming D helices of D1 and D2 proteins based on molecular dynamic simulations of a simplified model representing the reaction centre of photosystem II. Stability of the putative interhelical hydrogen bond network connecting D1 and D2 proteins was investigated experimentally with dynamic force spectroscopy using atomic force microscope. The results of both methods are in a full agreement with each other and reveal the key role of D1-Gly208 aminoacid in stability and functionality of photosystem II by providing milieu for weak interactions among three contact points at the cross of D helices: D1-Gly208 (O) and D2-Cys211 (O?), D1-Ser209 (O?) and D2-Ile204 (O), D1-Ser212 (O?) and D2-Gly207 (O). Mutation of the D1-Gly208 led to the increase in probability of the binding among the aforementioned aminoacids, undesirably strengthening the overall interactions among the proteins compromising photosynthetic capacity (D1-Ser208) or disabling of autotrophic growth (D1-Val208).
134	Light Reactions of Photosynthesis: Exploring Early Energy and Electron Transfers in Cyanobacterial Photosystem I via Optical Spectroscopy Antoine P. Martin (5930030) 14 December 2020 (has links) <p>Early processes following photon absorption by the photosynthetic pigment-protein complex photosystem I (PS I) have been the subject of decades of research, yet many questions remain in this area of study. Among the trickiest to investigate is the role of the PS I reaction center’s (RC’s) two accessory (A<sub>‑1</sub>) chlorophyll (Chl) cofactors as primary electron donors or acceptors, oxidizing the special pair (P<sub>700</sub>) of Chls or reducing a nominal primary electron acceptor (A<sub>0</sub>) Chl in the first electron transfer step. Such processes, which occur on a picosecond timescale, have long been studied via ultrafast spectroscopy, though difficulty lies in distinguishing among signals from early processes, which have similar lifetimes and involve many identical pigments. In this work, we used steady-state and ultrafast optical pump-probe spectroscopies on PS I trimers from wildtype and mutant strains of the cyanobacterium <i>Synechocystis</i> sp. PCC 6803 in which an asparagine amino acid residue near A<sub>‑1</sub> had been replaced with methionine on one or both sides of the RC. We also conducted an identical set of experiments on mutants in which A<sub>0</sub> was similarly targeted, as well as studied the effects on the A<sub>0</sub> absorption spectrum of a third category of mutations in which a peripheral H‑bond to A<sub>0</sub> was lost. Steady-state absorption spectroscopy revealed that many of these mutations caused mild Chl deficiencies in the light-capturing antenna of PS I without necessarily preventing organisms’ growth. More importantly, we determined that contrary to certain hypotheses, A<sub>‑1</sub> is the most likely true first electron acceptor, as reasoned from observing rapid triplet state formation in double A<sub>‑1</sub> mutants. We also concluded from non-additive detrimental effects of single-side mutations that if one RC branch is damaged at the level of A<sub>0</sub> or A<sub>‑1</sub>, electron transfer may be redirected along the intact branch. This may help explain the conservation of two functional RC branches in PS I over many generations of natural selection, despite the additional cost to organisms of manufacturing both.</p> Biophysics photosystem i reaction center photosynthesis ultrafast broadband photoluminescence optical spectroscopy photosynthetic excitons steady-state spectroscopy pump-probe spectroscopy mutant double mutant absorption spectrum laser spectroscopy femtosecond spectroscopy
135	Untersuchungen zur Funktion sauerstofftoleranter, NAD + -reduzierender Hydrogenasen und zu deren Anwendung in der lichtgetriebenen Wasserstoffproduktion in Cyanobakterien Karstens, Katja 02 February 2015 (has links) Die lösliche, NAD+-reduzierende Hydrogenase (SH) aus Ralstonia eutropha H16 ist eine Pyridinnukleotid-abhängige Hydrogenase. Das heißt, der Umsatz von H2 im Hydrogenasemodul des Enzyms ist an die Reduktion von NAD(P)+ im NAD(P)H:Akzeptor-Oxidoreduktasemodul gekoppelt. Die SH ist Vertreter des Subtyps, der auch in Gegenwart von O2 katalytisch aktiv ist. Dies wird ermöglicht durch eine reduktive Entfernung von O2, die nach dem aktuellen Modell abhängig ist vom rückläufigen e--Transport vom NADH:Akzeptor-Oxidoreduktasemodul zum aktiven [NiFe]-Zentrum in der großen Hydrogenaseuntereinheit. Der Einfluss des FeS-Clusters in der kleinen Hydrogenaseuntereinheit HoxY auf diesen Prozess wurde hier untersucht. Dabei konnte gezeigt werden, dass die vier hochkonservierten Cysteine C41, C44, C113 und C179 in HoxY an der Koordination des FeS-Zentrums beteiligt sind. Außerdem wurde das nahegelegene Cystein C39 als relevant für die Sauerstofftoleranz identifiziert. Weiterhin wurde gezeigt, dass das Tryptophan W42 aus HoxY essentiell für die Hydrogenaseaktivität der SH ist. Damit bestätigt sich, dass die Kinetik des rückläufigen e--Transports durch die Aminosäureumgebung des FeS-Clusters in HoxY beeinflusst ist. Ferner wurden in dieser Arbeit Ansätze zum Einsatz der SH aus R. eutropha in einer H2-produzierenden cyanobakteriellen Designzelle weiterverfolgt. Dazu wurden Hybridsysteme aus SH und cyanobakteriellem Photosystem I in vitro hinsichtlich ihrer Fähigkeit zur lichtgetriebenen H2-Produktion untersucht. Außerdem wurde an einem heterologen Expressionssystem der SH für Cyanobakterien gearbeitet. Weiterhin wurde die SH aus Rhodococcus opacus MR11 als komplementäres Modellsystem für O2-tolerante Pyridinnukleotid-abhängige Hydrogenasen etabliert. Dieser zur SH aus R. eutropha homologe Komplex hatte in früheren Arbeiten Vorteile für spektroskopische Studien offenbart und wurde hier erstmals im direkten Vergleich zur SH aus R. eutropha biochemisch und spektroskopisch charakterisiert. / The soluble, NAD+-reducing hydrogenase (SH) from Ralstonia eutropha H16 is a pyridine nucleotide-dependent hydrogenase. In these types of enzymes the conversion of H2 in the hydrogenase module of the complex is coupled to the reduction of NAD(P)+ in the NAD(P)H:acceptor oxidoreductase module. The SH belongs to a subtype that is catalytically active also in the presence of O2. This O2 tolerance is enabled by a reductive removal of O2, which according to the current model depends on a reverse e- flow from the NADH:acceptor oxidoreductase module to the active [NiFe] site in the large hydrogenase subunit. The impact of the FeS cluster in the small hydrogenase subunit HoxY on this process was analyzed in this study. Thereby it was shown that the four highly conserved cysteines C41, C44, C113 and C179 in HoxY are involved in the coordination of the FeS center. Further the nearby cysteine C39 was identified to be relevant for the O2 tolerance of the SH. Additionally we found the tryptophan W42 to be essential for the hydrogenase activity of the SH. Thus it was confirmed that the kinetic of the reverse e- transport is affected by the amino acid environment of the FeS cluster in HoxY. In addition, approaches for using the SH from R. eutropha in H2 producing cyanobacterial design cells were pursued. On one hand hybrid systems consisting of the SH and cyanobacterial photosystem I were analyzed in vitro for their capacity to produce H2 in a light dependent manner. On the other hand work on a heterologous expression system of the SH for Cyanobacteria was continued. Furthermore the SH from Rhodococcus opacus MR11 was established as complementary model system for O2-tolerant pyridine nucleotide-dependent hydrogenases. This complex, which is homologous to the SH from R. eutropha, has revealed advantages for spectroscopic analysis in earlier studies. Here it was characterized biochemically and spectroscopically for the first time in direct comparison with the SH from R. eutropha. Photosystem I Cyanobakterien Heterologe Expression Wasserstoff Hydrogenase Ralstonia eutropha Sauerstofftoleranz Eisenschwefelcluster HoxY NADH Rhodococcus opacus Heterologe Produktion photosystem I cyanobacteria heterologous expression hydrogen iron sulfur cluster oxygen tolerance Ralstonia eutropha hydrogenase HoxY NADH Rhodococcous opacus heterologous production 570 Biowissenschaften, Biologie 32 Biologie WN 8120 ddc:570
136	Propriétés physico-chimiques et structurales de deux hémoprotéines de cyanobactérie thermophile / Physico-chemical and structural properties of two hemeproteins from thermophile cyanobacteria Lai-Thi, Thanh-Lan 18 September 2015 (has links) La photosynthèse permet de convertir l’énergie solaire en énergie chimique. Ce processus met en jeu un grand nombre de protéines et complexes protéiques. Le premier complexe de la chaîne photosynthétique est le photosystème II où a lieu l’oxydation de l’eau. Le PSII est composé des protéines D1 et D2. Chez la cyanobactérie thermophile Thermosynechococcus elongatus, il y a trois gènes qui codent trois protéines D1 différentes. La première partie de la thèse décrit le développement d’outils protéomiques basés sur les gels d’électrophorèse 2D pour étudier le protéome des trois différents variants, qui expriment chacun une seule protéine pour D1. Peu de différences ont été trouvées. Toutefois, un seul des variants exprime Tll0287. La deuxième partie de la thèse décrit la caractérisation de Tll0287 avec différents techniques : spectroscopies d’absorption UV-visible ou de résonance Raman et spectro-électrochimie. Tll0287 a été identifié comme un cytochrome de type c, mais il présente beaucoup de caractéristiques inattendues. Les spectres d’absorption UV-visible et de résonance Raman de Tll0287 réduit montrent une dépendance vis-à-vis du pH. Deux formes d’hèmes sont présents dans chacun des états oxydé et réduit. Un changement du ligand cystéine a été observé quand l’hème est réduit. Les titrages redox présentent de multiples potentiels à pH 10 et pH 5. Tll0287 peut fixer une molécule de CO à pH 7,6. Ces caractéristiques suggèrent que Tll0287 pourrait être une protéine senseur. De plus, la structure cristallographique montre que Tll0287 n’a pas un repliement classique d’un cytochrome de type c mais celui d’une protéine senseur. Les mutants de délétion du gène tll0287 ont été construits et aideront à comprendre la fonction de ce nouveau cytochrome. La troisième partie décrit l’étude de PsbV2 : un autre cytochrome de type c. Afin d’obtenir en quantité suffisante la protéine pour permettre sa caractérisation, elle a été surexprimée dans un système homologue en utilisant le promoteur de l’enzyme de la rubisco. Le potentiel redox de PsbV2 a été déterminé, comme étant très bas, inférieur à -460 mV (vs SHE, pH 5). Le spectre d’absorption UV-visible de la forme réduite a été caractérisé. La structure cristallographique de PsbV2 a été résolue et a révélé une cystéine comme ligand axial et un repliement proche de celui de cytochromes connus de T.elongatus. Bien que Tll0287 et PsbV2 présentent une cystéine comme ligand axial, leurs structures et leurs propriétés physico-chimiques suggèrent que leurs fonctions sont bien différentes. Une contribution majeure de cette thèse est la caractérisation d’un nouveau senseur à hème de type c chez les cyanobactéries et le développement d’outils nécessaires pour son étude. / Photosynthesis converts solar energy into chemical energy. This process involves a large number of proteins and protein complexes. The first protein complex in the photosynthetic chain is Photosystem II within the oxidation of water takes place. PSII is composed of the D1 and D2 proteins. In the thermophile cyanobacterium Thermosynechococcus elongatus, three genes encoded three different D1 proteins. The first part of this thesis describes the development of proteomics tools based on 2D gel-electrophoresis to study the proteome of three different variants, each expressing a single different D1 protein. Very few differences were found. However, only one expressed the protein Tll0287. The second part of the thesis describes the characterization of Tll0287. It was characterized using different techniques: electronic absorption and Raman resonance spectroscopies and spectro-electrochemistry. Tll0287 has been previously identified as a c-type cytochrome, but it presents some unexpected characteristics. The UV-visible absorption and Raman resonance spectra of reduced Tll0287 show a pH dependence. The reduced and oxidized states each had two different forms of the heme. A switch of ligands from a cysteine to histidine was observed in the reduced state. Redox titration showed multiple midpoints at pH 10 and 5. Tll0287 was shown to fix a CO molecule at pH 7.6. These physical properties suggested that Tll0287 could be a sensor. The crystallographic studies reveal that Tll0287 does not have a classical c-type cytochrome fold and is similar to other known sensor proteins, strengthening the hypothesis that it is a sensor. Deletion mutants were constructed that will help to better understand the function of this new cytochrome. The third part describes a study of the PsbV2, another c-type cytochrome. In order to obtain sufficient quantities to carry out characterization of this protein, it was overexpressed in a homologous system using the promotor of the rubisco enzyme. The redox midpoint potential of PsbV2 was found to be very low, below -460 mV (vs SHE, pH 5). The UV-visible absorption spectrum of the reduced form was determined. The crystallographic structure of PsbV2 was solved and reveals an axial cysteine ligand. Although both Tll0287 and PsbV2 share this feature, their different structures and physico-chemical properties suggest that their functions are unlikely to be similar. A major contribution of this thesis is the characterization of a new c-type cytochrome sensor in cyanobacteria and the development of proteomic tools required to study it. Cyanobacterie PsbA Photosystème II Protéine D1 Protéomique Hémoprotéine Tll0287 PsbV2 Cytochrome de type c Titrage redox Coordination de l'hème Spectroscopie de résonnance Raman Cyanobacteria PsbA Photosystem II D1 protein Proteomic Hemeprotein Tll0287 PsbV2 C-type cytochrome Redox titration Heme coordination Raman spectroscopy
137	Progress Toward Time-Resolved X-ray Spectroscopy of Metalloproteins Scott C. Jensen (5929838) 16 January 2019 (has links) <p>Metalloproteins, or proteins with a metal ion cofactor, are essential for biological function of both lower and higher level organisms. These proteins provide a multitude of functions from molecular transport, such as the hemoglobin transport of oxygen, to biologically important catalytic processes. As an example case, photosystem II (PSII) is studied as a representative metalloprotein. It was chosen based on the potential impact in the energy sector due to its ability to perform water oxidation using solar based energy. Understanding mechanisms by which the Mn<sub>4</sub>Ca cluster inside PSII, also known as the oxygen evolving complex (OEC), can store energy as redox equivalents for splitting water will be essential for future development of analogous artificial systems. By using time resolved x-ray spectroscopy, the electron structure of the metal in the protein was probed through the catalytic cycle. While the applications mentioned herein are based on PSII from spinach, the developments in time-resolved x-ray spectroscopy techniques are also applicable to other metalloproteins.</p><p></p><p>By creating a new x-ray spectrometer we were able to capture the difference in x-ray emission spectra between two compounds differing in a single metal bound ligand, i.e. Mn<sup>IV</sup>-OH and Mn<sup>IV</sup>=O. This both establishes the functionality of the x-ray emission spectrometer and provides useful insight into the expected changes upon an oxygen double bond formation. This change in spectroscopic signal is discussed in context of the OEC which has been hypothesized to form a Mn<sup>IV</sup>=O state.</p><p></p><p>A new sample delivery system and further developments to the x-ray spectrometer enabled both time-resolved x-ray absorption and time-resolved x-ray emission of PSII. These experiments show the potential of synchrotron sources for time-resolved x-ray spectroscopy. From our x-ray absorption measurements we were able to follow the electronic structure changes in time using a single incident photon energy. From the kinetic traces obtained, we show possible alternative interpretations of previous results showing a delay in reduction during the final step in water oxidation. From the x-ray emission spectroscopy (XES) measurements of PSII we were able to reproduce previous results within a limited collection time and give estimates for data size requirements for metalloproteins using this spectrometer. Between the results of both these measurements, we show the improved capability for time resolved measurements at synchrotrons.</p><p>The development of x-ray free electron lasers (XFELs) has also opened many opportunities for understanding faster electronic dynamics by providing femtosecond x-ray pulse durations with ~10<sup>12</sup> photons per pulse. While theoretical modeling of distortions to crystallographic data have been performed, little to no work has been done to understand under what conditions such an intense pulse will have on an impact on emission spectra. Here an atomistic model was developed, and data collected, to clarify the effects of sequential ionization, i.e. two single photons absorbed by the same atom at different times during a single pulse. Experimentally we found that XFELs easily achieve flux densities that invoke a different response than is classically observed for single photon absorption and emission for Mn<sup>II</sup> which was used as a representative case for 3d transition metals in general. We also give parameters by which the onset of this damage can be predicted and an approximation to its effect on 3d transition metals. Additionally this work guides the work of future XFEL facilities as it shows that shorter pulses, currently believed to be able to escape x-ray induced distortions to crystallography data, is not a viable method for overcoming changes in x-ray emission spectra.</p><div><br></div> Biological Physics X-ray Free Electron Laser X-ray Emission Spectroscopy X-ray Spectrometer Design Photosystem II Sequential X-ray Ionization
138	Physiological adaptations in two ecotypes of Fucus vesiculosus and in Fucus radicans with focus on salinity Gylle, A Maria January 2011 (has links) The in origin intertidal marine brown alga Fucus vesiculosus L. grow permanently sublittoral in the brackish Bothnian Sea, side by side with the recently discovered F. radicans L. Bergström et L. Kautsky. Environmental conditions like salinity, light and temperature are clearly different between F. vesiculosus growth sites in the Bothnian Sea (4-5 practical salinity units, psu; part of the Baltic Sea) and the tidal Norwegian Sea (34-35 psu; part of the Atlantic Ocean). The general aims of this thesis were to compare physiological aspects between the marine ecotype and the brackish ecotype of F. vesiculosus as well as between the two Bothnian Sea species F. vesiculosus and F. radicans. The result in the study indicates a higher number of water soluble organic compounds in the marine ecotype of F. vesiculosus compared to the brackish ecotype. These compounds are suggested to be compatible solutes and be due to an intertidal and sublittoral adaptation, respectively; where the intertidal ecotype needs the compounds as a protection from oxygen radicals produced during high irradiation at low tide. The sublittoral ecotype might have lost the ability to synthesize these compound/compounds due to its habitat adaptation. The mannitol content is also higher in the marine ecotype compared to the brackish ecotype of F. vesiculosus and this is suggested to be due to both higher level of irradiance and higher salinity at the growth site. 77 K fluorescence emission spectra and immunoblotting of D1 and PsaA proteins indicate that both ecotypes of F. vesiculosus as well as F. radicans have an uneven ratio of photosystem II/photosystem I (PSII/PSI) with an overweight of PSI. The fluorescence emission spectrum of the Bothnian Sea ecotype of F. vesiculosus however, indicates a larger light-harvesting antenna of PSII compared to the marine ecotype of F. vesiculosus and F. radicans. Distinct differences in 77 K fluorescence emission spectra between the Bothnian Sea ecotype of F. vesiculosus and F. radicans confirm that this is a reliable method to use to separate these species. The marine ecotype of F. vesiculosus has a higher photosynthetic maximum (Pmax) compared to the brackish ecotype of F. vesiculosus and F. radicans whereas both the brackish species have similar Pmax. A reason for higher Pmax in the marine ecotype of F. vesiculosus compared to F. radicans is the greater relative amount of ribulose-1.5-bisphosphate carboxylase/oxygenase (Rubisco). The reason for higher Pmax in marine ecotype of F. vesiculosus compare to the brackish ecotype however is not due to the relative amount of Rubisco and further studies of the rate of CO2 fixation by Rubisco is recommended. Treatments of the brackish ecotype of F. vesiculosus in higher salinity than the Bothnian Sea natural water indicate that the most favourable salinity for high Pmax is 10 psu, followed by 20 psu. One part of the explanation to a high Pmax in 10 psu is a greater relative amount of PsaA protein in algae treated in 10 psu. The reason for greater amount of PsaA might be that the algae need to produce more ATP, and are able to have a higher flow of cyclic electron transport around PSI to serve a higher rate of CO2 fixation by Rubisco. However, studies of the rate of CO2 fixation by Rubisco in algae treated in similar salinities as in present study are recommended to confirm this theory. / Fucus vesiculosus L. (Blåstång) är en brunalg som i huvudsak växer i tidvattenzonen i marint vatten men arten klarar också att växa konstant under ytan i det bräckta Bottenhavet. Norska havet och den del av Bottenhavet, där algerna är insamlade i denna studie, har salthalterna 34-35 psu (praktisk salthaltsenhet) respektive 4-5 psu. F. radicans L. Bergström et L. Kautsky (Smaltång) är en nyligen upptäckt art (2005) som har utvecklats i Bottenhavet. F. radicans och Bottenhavets ekotyp av F. vesiculosus växer sida vid sida och har tidigare ansetts vara samma art. Sett till hela Östersjön, så ändras ytans salthalt från 25 till 1-2 psu mellan Östersjöns gräns mot Kattegatt och norra Bottenviken. Den låga salthalten i Östersjön beror på det höga flödet av sötvatten från älvarna och på ett litet inflödet av saltvatten i inloppet vid Kattegatt. Salthaltsgradienten är korrelerad med antalet arter som minskar med minskad salthalt. Östersjön är ett artfattigt hav och de arter som finns är till stor del en blandning av söt- och saltvattenarter. Det finns bara ett fåtal arter som är helt anpassade till bräckt vatten och F. radicans är en av dem. Exempel på miljöskillnader för F. vesiculosus i Norska havet och i Bottenhavet är salthalten, tidvattnet, ljuset och temperaturen. Tidvattnet i Norska havet gör att algerna växlar mellan att vara i vattnet och på land, vilket utsätter algerna för stora ljusskillnader, snabba och stora temperaturväxlingar samt även torka. De alger som växer i Bottenhavet har däremot en jämnare och lägre temperatur, istäcke på vintern och mindre tillgång på ljus eftersom de alltid lever under vattenytan. Skillnaderna i miljön mellan växtplatserna leder till skillnader i fysiologiska anpassningar. Anledningen till att F. vesiculosus och F. radicans valdes som studieobjekt i denna avhandling är att de är viktiga nyckelarter i Bottenhavet. F. vesiculosus och F. radicans är de enda större bältesbildande alger som finns i det artfattiga ekosystemet och de används därför flitigt som mat, gömställe, parningsplats och barnkammare för t.ex. fisk. Att de är nyckelarter gör det angeläget att försöka förstå hur algerna är anpassade och hur de reagerar på miljöförändringar för att få veta hur de kan skyddas och bevaras. F. radicans inkluderades även för att se hur en naturlig art i Bottenhavet är anpassad i jämförelse med den invandrade F. vesiculosus. Marin F. vesiculosus inkluderades för att vara en artreferens från artens naturliga växtplats. Studien visar att det finns fler vattenlösliga organiska substanser (finns vissa organiska substanser som har en proteinskyddande funktion) i den marina ekotypen av of F. vesiculosus än i Bottenhavets ekotyp. Anledningen till detta föreslås vara en anpassning till att växa i tidvattenzonen. Vid lågvatten utsätts F. vesiculosus från Norska havet för starkt ljus, uttorkning, och snabba temperatur- växlingar vilket gör att den kan behöva dessa organiska substanser som skydd mot fria syreradikaler som bildas under lågvattenexponeringarna. F. vesiculosus från Bottenhavet har troligen mist förmågan att syntetisera dessa substanser på grund av anpassning till att hela tiden växa under ytan. Mängden mannitol (socker) är högre i den marina ekotypen av of F. vesiculosus än i Bottenhavets ekotyp. Detta föreslås bero på högre fotosyntetiskt maximum i F. vesiculosus från Norska havet jämfört med ekotypen från Bottenhavet. Skillnaden i fotssyntetiskt maximum är bland annat kopplat till ljus- och salthaltskillnaden på algernas växtplatser. Denna teori styrks av att både fotosyntesen och halten av mannitol ökar i Bottenhavets ekotyp när den behandlas i högre salthalt. Studien visar även att båda ekotyperna av F. vesiculosus samt F. radicans har ett ojämnt förhållande mellan fotosystem II och I (PSII och PSI) med en dominans av PSI. Denna slutsats är baserad på fluorescens emissions mätningar vid 77 K (-196 °C) och mätning av den relativa mängden D1 protein (motsvarar PSII) och PsaA protein (motsvarar PSI). F. vesiculosus från Bottenhavet visar ett emission spektrum som pekar mot en jämnare fördelning av PSII och PSI jämfört med den marina ekotypen och F. radicans. Detta stämmer dock inte med förhållandet mellan D1/PsaA som indikerar att alla tre har mer PSI än PSII. Förklaringen till avvikelsen mellan metoderna antas vara att F. vesiculosus från Bottenhavet har större ljus-infångande antennpigment än marin F. vesiculosus och F. radicans. De tydliga skillnaderna i 77 K fluorescens emission spektra mellan Bottenhavets F. vesiculosus och F. radicans visar att denna metod kan användas som säker artidentifiering. Den marina ekotypen av F. vesiculosus har högre fotosyntetiskt maximum än de båda arterna från Bottenhavet. Mätningar av den relativa mängden av enzymet Rubisco, viktigt för upptaget av koldioxid hos växter och alger, visar att mängden enzym är en sannolik förklaring till skillnaden i fotosyntetiskt maximum mellan den marina ekotypen av F. vesiculosus och F. radicans och detta är troligen en normal artskillnad. Mängden Rubisco kan dock inte förklara skillnaden i fotosyntetiskt maximum mellan de båda ekotyperna av F. vesiculosus. För att undersöka vad skillnaden mellan dessa två beror på så föreslås istället mätningar av Rubisco’s koldioxidfixeringshastighet. Det är en ökning av fotosyntetiskt maximum i Bottenhavets ekotyp av F. vesiculosus när den behandlas i högre salthalt (10, 20 och 35 psu) och det högsta fotosyntetiska maximumet uppmättes i alger som behandlats i 10 psu. Denna ökning beror inte på ökning i den relativa mängden av Rubisco. Ökningen i fotosyntesen speglas dock av en ökning av den relativa mängden PsaA. Detta antas bero på att det behövs mer energi i form av ATP och att en ökning av detta kan ske på grund av att mer PsaA kan driva den cykliska elektrontransporten i fotosyntesreaktionen. Ökat behov av ATP antas bero på en ökning av Rubisco aktiviteten men mätning av aktiviteten krävs för att bekräfta detta. Bothnian Sea brackish brown algae D1 77 K fluorescence emission Fucus vesiculosus Fucus radicans light-harvest antenna mannitol marine NMR Norwegian Sea quantum yield photosynthetic maximum capacity (Pmax) photosystem (PSI PSII) PsaA Rubisco salinity. Biology Biologi Plant physiology Växtfysiologi
139	Solar Energy Conversion in Plants and Bacteria Studied Using FTIR Difference Spectroscopy and Quantum Chemical Computational Methodologies Parameswaran, Sreeja 15 July 2009 (has links) This dissertation presents a study of the molecular mechanism underlying the highly efficient solar energy conversion processes that occur in the Photosystem I (PS I) reaction centers in plants and bacteria. The primary electron donor P700 is at the heart of solar energy conversion process in PS I and the aim is to obtain a better understanding of the electronic and structural organization of P700 in the ground and excited states. Static Fourier Transform Infra-Red (FTIR) difference spectroscopy (DS) in combination with site directed mutagenesis and Density Functional Theory (DFT) based vibrational frequency simulations were used to investigate how protein interactions such as histidine ligation and hydrogen bonding modulate this organization. (P700+-P700) FTIR DS at 77K were obtained from a series of mutants from the cyanobacterium Synechocystis sp. 6803 (S. 6803) where the amino acid residues near the C=O groups of the two chlorophylls of P700 where specifically changed. (P700+-P700) FTIR DS was also obtained for a set of mutants from C. reinhardtii where the axial ligand to A0-, the primary electron acceptor in PS I was modified. The FTIR DS obtained from these mutants provides information on the axial ligands, the hydrogen bonding status as well as the polarity of the environment of specific functional groups that are part of the chlorophyll molecules that constitute P700. Assignment of the FTIR bands to vibrational modes in specific types of environment is very difficult. In order to assist the assignment of the difference bands in experimental spectra DFT based vibrational mode frequency calculations were undertaken for Chl-a and Chl-a+ model molecular systems under different set of conditions; in the gas phase, in solvents using the Polarizable Continuum Model (PCM), in the presence of explicit solvent molecules using QM/MM methods, and in the presence of axial ligands and hydrogen bonds. DFT methods were also used to calculate the charge, spin and redox properties of Chl-a/Chl-a’ dimer models that are representative of P700, the primary electron donor in PS I. Photosynthesis Photosystem I (PS I) P700 Fourier transform infrared (FTIR) Synechocystis sp. PCC 6803 (S. 6803) Density Functional Theory (DFT) Chlorophyll a (Chl-a) Polarizable Continuum Model (PCM) QM/MM Astrophysics and Astronomy Physics
140	Stress response in the cyanobacterium Synechocystis sp. PCC 6803 Miranda, Helder January 2011 (has links) Adaptation to environmental changes is important for the survival of living organisms. Under extreme abiotic conditions, organic molecules (such as lipids, proteins and nucleic acids) are prone to damage. Under these conditions stress response mechanisms are activated, either to prevent the source of damage or to promote the rapid turnover of damaged molecules. Like all photoautotrophic organisms, cyanobacteria are sensitive to high light intensity and oxidative stress, which induces damage to the photosynthetic apparatus. My thesis is divided in two subjects related to particular stress responses in the cyanobacterium Synechocystis sp. PCC 6803: 1) the role of Deg/HtrA proteases and 2) investigations on the small CAB-like proteins. Deg/HtrA proteases are ATP-independent serine endopeptidases with a characteristic C-terminal PDZ domain. These proteases are largely dispersed among living organisms, with many different functions, mostly involved in protein quality control. The genome of Synechocystis sp. PCC 6803 contains three genes coding for Deg/HtrA proteases: HtrA, HhoA and HhoB. These proteases are essential for survival under high light and heat stress, and may overlap in their functions. During my Ph.D. studies I focused on the identification of the precise localization of the Deg/HtrA proteases in the cyanobacterial cell, analyzed the biochemical properties of recombinant Synechocystis Deg/HtrA proteases in vitro and adopted proteomic and metabolomic approaches to study the physiological importance of these proteases. My data show that Deg/HtrA proteases are not only important in stress response mechanisms under adverse conditions, but are also involved in the stabilization of important physiological processes, such as polysaccharides biosynthesis and peptidoglycan turnover. The small CAB-like proteins (SCPs) belong to the light harvesting-like family of stress induced proteins and are thought to be involved in the photoprotection of the photosynthetic apparatus. Five small CAB-like proteins where identified in Synechocystis sp. PCC 6803 (ScpA-E). In my studies I identified another relative to the SCPs, LilA, which I found to be co-transcribed with ScpD. I also focused on the subcellular localization and identification of potential interaction partners of the SCPs. Cyanobacteria High light heat stress ROS Photosynthesis Photosystem II Deg/HtrA proteases small CAB-like proteins Refraction-2D™ MALDI-TOF 2D-gel GC-MS PCA OPLS-DA EPS S-layer Biochemistry Biokemi

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