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11	The effect of nitrogen starvation on PSI and PSII activity in pea (Pisum sativum) Ek, Louise January 2006 (has links) <p>This investigation addresses how photosynthetic efficiency is affected when pea (Pisum sativum) plants are restricted to a sole nitrogen source (i.e. ammonium or nitrate). The pea plants were watered with different nutrient solutions without NO3- or NH4+ for different time-periods in order to assay for nitrogen content. The soluble ammonium and nitrate content was measured throughout the entire growth period. No major differences were observed in nitrogen content during the starvation period up to 25 days. For technical reasons, cultivation of plants could not be extended beyond this time. The chloroplasts and thylakoids were isolated after 25 days and assayed for chlorophyll contents and photosynthetic activity.</p><p>The outcome of these tests indicates a small but unambiguous decrease in the photosynthesis activity for all treatments, relative the control.</p> pisum sativum plant nutrition nitrogen photosystem PSI PSII photosynthes chloroplast thylakoid
12	Functions of REP27 and the low molecular weight proteins PsbX and PsbW in repair and assembly of photosystem II Garcia Cerdan, Jose Gines January 2009 (has links) Oxygenic photosynthesis is the major producer of both oxygen and organic compounds on earth and takes place in plants, green algae and cyanobacteria. The thylakoid membranes are the site of the photosynthetic light reactions that involve the concerted action of four major protein complexes known as photosystem II (PSII), cytochrome b6f complex, ATP synthase and photosystem I (PSI). The function of PSII is of particular interest as it performs the light–driven water splitting reaction driving the photosynthetic electron transport. My thesis addressed different aspects of PSII assembly and the functions of its low molecular weight PSII subunits PsbX and PsbW. Photosynthesis in green algae and higher plants is controlled by the nucleus. Many proteins of nuclear origin participate in the regulation of the efficient assembly of the photosynthetic protein complexes. In this investigation we have identified one of these nuclear encoded auxiliary proteins of photosystem II, REP27, which participates in the assembly of the D1 reaction center protein and repair of photodamaged PSII in the green algae Chlamydomonas reinhardtii. Interestingly, PSII is specially enriched in Low Molecular Weight (LMW) subunits that have masses less than 10kDa. These proteins account for more than the half of the PSII subunits. Several questions remains poorly understood regarding the LMW: Which is their evolutionary origin? What function do they perform in the protein complex? Where are they located in the protein structure? In this investigation the functions of two of these LMW subunits (PsbX and PsbW) have been studied using antisense inhibition and T-DNA knockout mutant plants in Arabidopsis thaliana. Deficiency of the PsbX protein leads to impaired accumulation and functionality of PSII. Characterization of PsbW knock-out plants show that PsbW participates in stabilization of the macro-organization of PSII and the peripheral antenna (Light Harvesting Complex, LHCII) in the grana stacks of the chloroplast, also known as PSII-LHCII supercomplexes. Photosynthesis photosystem II reaction center PSII-LHCII supercomplex antisense plant T-DNA knockout plant auxiliary protein
13	The effect of nitrogen starvation on PSI and PSII activity in pea (Pisum sativum) Ek, Louise January 2006 (has links) This investigation addresses how photosynthetic efficiency is affected when pea (Pisum sativum) plants are restricted to a sole nitrogen source (i.e. ammonium or nitrate). The pea plants were watered with different nutrient solutions without NO3- or NH4+ for different time-periods in order to assay for nitrogen content. The soluble ammonium and nitrate content was measured throughout the entire growth period. No major differences were observed in nitrogen content during the starvation period up to 25 days. For technical reasons, cultivation of plants could not be extended beyond this time. The chloroplasts and thylakoids were isolated after 25 days and assayed for chlorophyll contents and photosynthetic activity. The outcome of these tests indicates a small but unambiguous decrease in the photosynthesis activity for all treatments, relative the control. pisum sativum plant nutrition nitrogen photosystem PSI PSII photosynthes chloroplast thylakoid
14	Potassium channel AtTPK5 : An essential or redundant regulator of photosynthesis in Arabidopsis? Shiki Baluch, Behrad January 2011 (has links) It has previously been stated that K+-ions in a plant cell have a counter-balancing role in which the efflux of K+-ions from the thylakoid lumen charge-balance the light-induced proton pumping that is known to occur across the thylakoid membrane, and this in turn stabilizes photosynthetic activity. In the present study, two different types of plants of the same ecotype (Col-0) of Arabidopsis thaliana have been studied: a wild-type and a T-DNA exon-mutant (tpk5-e) that has lost the expression of the protein known as Tandem-pore K+- channel (AtTPK5). The plants were grown in a hydroponic system under normal light conditions with 70% humidity. Homozygous (HM) tpk5-e mutant plants were screened using PCR and gene specific primers. Further, the photosynthetic activity was measured in 4 hour light-adapted plants and the photosynthetic activity of the tpk5-e mutant proved not to be significantly different in comparison to the wild-type when measuring the electron transport rate (ETR). Furthermore, the O2-evolution was also measured in 4 hour light-adapted plants and the tpk5-e mutant's O2-evolution proved to be significantly lower in the tpk5-e mutant in comparison to the wild-type under high light conditions. The plant fitness of the wild-type and tpk5-e mutant was also different judging from phenotypic traits such as chlorophyll expression. However, the measured chlorophyll amount of pigments chlorophyll a and b proved not to be significantly different in the tpk5-e mutant in comparison to the wild-type. Chloroplast thylakoid TPK PCR ETR O2-evolution PAR PSII. NATURAL SCIENCES NATURVETENSKAP
15	Limitation of photosynthetic carbon metabolism in South African soybean genotypes in response to low night temperatures / Abram Johannes Strauss Strauss, Abram Johannes January 2008 (has links) Thesis (Ph.D. (Botany))--North-West University, Potchefstroom Campus, 2009. Calvin-cycle Chilling tolerance Chlorophyll a fluorescence Dark chilling Low soil temperature Photosynthesis PSII function Soybean
16	Limitation of photosynthetic carbon metabolism in South African soybean genotypes in response to low night temperatures / Abram Johannes Strauss Strauss, Abram Johannes January 2008 (has links) Thesis (Ph.D. (Botany))--North-West University, Potchefstroom Campus, 2009. Calvin-cycle Chilling tolerance Chlorophyll a fluorescence Dark chilling Low soil temperature Photosynthesis PSII function Soybean
17	Role FtsH proteas v sinici Synechocystis sp. PCC 6803 / Role of FtsH proteases in the cyanobacterium Synechocystis sp. PCC 6803 KRYNICKÁ, Vendula January 2015 (has links) This thesis focuses on the functional and structural characterization of FtsH proteases in Synechocystis PCC 6803. One of the aims was to determine localization and subunit organization of FtsH homologues in Synechocystis cells using GST and GFP tagged FtsH derivatives. The main result of the thesis is identification of two FtsH hetero-oligomeric complexes and one homo-oligomeric complex in Synechocystis cells. The large part of the thesis is aimed at establishing the role of the first hetero-oligomeric complex, FtsH2/FtsH3, in quality control of Photosystem II and at identification of a mechanism, how its substrate proteins D1 and D2 are recognized. Another part is dedicated to characterization of the second hetero-oligomeric complex, FtsH1/FtsH3, which consists of two essential FtsH homologues and which is here identified as an important regulatory element in maintaining iron homeostasis.
18	Role izoforem PsbO v Arabidopsis thaliana / Role of PsbO isoforms in Arabidopsis thaliana Svoboda, Václav January 2016 (has links) Role of PsbO isoforms in Arabidopsis thaliana Abstract Photosystem II (PSII) uses sunlight to catalyze water oxidation and reduce plastoquinone. Water oxidation takes place in oxygen evolving complex (OEC). OEC is stabilized by extrinsic subunits of PSII. The largest and most important of them is PsbO, manganese-stabilizing protein which can be found in all known oxygenic photosynthetic organisms. Model plant Arabidopsis thaliana expresses two isoforms of psbO gene, namely PsbO1and PsbO2.Mutants psbo1 and psbo2 lacking PsbO1 and PsbO2, respectively, recently brought new findings on the particular roles of isoforms in maintaining photosynthesis. PsbO1 is commonly considered as the main isoform facilitating water splitting, whereas PsbO2 is believed to be involved in PSII repair process (replacement of photodamaged D1 subunit). This work focuses on particular roles of Arabidopsis PsbO isoforms in maintaining photosynthesis with special focus on response to light stress. Mutants psbo1, psbo2 and wild type plants Col-0 were used for extensive biochemical investigation. Our aim was to find out what is the impact on overall thylakoid structure and composition in mutants. Furthermore, to investigate response to light stress in wild type regarding to yields of particular subcompartments, changes in photosystem II...
19	Control and function of two ferrochelatase isoforms in Arabidopsis thaliana Fan, Tingting 18 March 2019 (has links) Die Tetrapyrrol-Biosynthese der Pflanzen ist ein hoch konservierter Prozess, indem sich die Häm- und Chlorophyllsynthese gemeinsame Syntheseschritte von der 5-Aminolävulinsäure (ALA)- bis hin zur Protoporphyrin IX (Proto)-Bildung teilen. Zur Hämsynthese sind in Arabidopsis thaliana zwei Isoformen der Ferrochelatase (FC) vorhanden, welche die Insertion von Eisenionen in Proto katalysieren. In dieser Arbeit wurden fc1 und fc2 Mutanten analysiert und für Komplementationsversuche mit nativen und modifizierten FC1/FC2-Sequenzen genutzt. Die in der fc1-2 Mutante gestörte Embryonalentwicklung infolge des FC1 Mangels konnte durch Expression eines pFC1::FC1 Genkonstruktes komplementiert werden. Die Expression von FC2 unter dem FC1 Promoter (pFC1::FC2) konnte die fc1-2 Mutante unter Standard-Wachstumsbedingungen vollständig komplementieren, jedoch nicht unter Salzstress. Zusätzlich zu den Komplementationsversuchen der fc1 Mutanten wurde auch eine fc2 Null-Mutante zur Expression der beiden genomischen FC Sequenzen herangezogen, um die spezifischen Funktionen der FC2-Varianten zu untersuchen. Während die pFC1FC2 (fc2/fc2) Pflanzen unter Dauerlicht eine vollständige Komplementation zeigten, konnte unter Kurztagbedingungen nur eine partielle Komplementation beobachtet werden. Versuche geben erste wichtige Hinweise, dass auch FC2 an der Regulation der ALA-Synthese infolge ihrer Interaktion mit PORB beteiligt ist. Dies deutet darauf hin, dass der Häm- und der Chlorophyllzweig eine gemeinsame Regulation der ALA-Synthese teilen, um das Gleichgewicht der TBS zu wahren. Neben der Funktion der FC2 in der Regulation der TBS konnte die vorliegende Arbeit ebenfalls die Rolle der FC2 in der Assemblierung der PSII-LHCII Superkomplexe offenlegen. Basierend auf den Ergebnissen, dieser Studie können Modelle für die funktionale Verteilung der beiden FC-Isoformen in unterschiedlichen Geweben und Entwicklungsstadien, sowie die Funktionen in verschiedenen biologischen Prozessen postuliert werden. / In plants, heme and chlorophyll synthesis share the common synthetic steps from 5- aminolevulinic acid (ALA) formation to Protoporphyrin IX (Proto) production in the conserved Tetrapyrrole biosynthesis (TBS) pathway. Arabidopsis thaliana utilizes two ferrochelatses (FC) to catalyse the insertion of ferrous iron into Proto to yield heme. In this study, the fc1 and fc2 defective mutants have been re-analysed and used for complementation tests with expression of a native or modified FC1/FC2 sequence. The pFC1FC1 (fc1/fc1) complementation plants confirmed that the defective embryo maturation in homozygous fc1-2 seeds is attributed to a lack of FC1. Expression of FC2 under the FC1 promoter contributed to a full complementation of fc1-2 under standard growth conditions, but not under salt stress. A fc2 null mutant has been used to express the two FC genomic sequences to substantiate the specific functions of FC2. Expression of FC2 under its own promoter was able to rescue fc2-2 mutants under both SD and CL conditions. However, pFC2FC1 (fc2/fc2) plants showed a partial complementation under SD condition. Via multiple interaction assays and mutant analyses, this thesis uncovered a mechanism of FC2 action on ALA synthesis regulation via interaction of FC2 and PORB. The results indicate that both branches of heme and chlorophyll synthesis share a common regulation to balance the TBS pathway. Apart from a role of FC2 involved in the regulation of TBS pathway, the presented study also revealed FC2 function in the assembly of the PSII-LHCII supercomplexes. Based on all the results obtained in this study, the functional distribution models of the two FC in different tissues and development stages, as well as diverse biological processes, have been proposed. In addition, to which extent that FC1/FC2 could compensate the function of the other isoform has been discussed. Ferrochelatase Embryo-Entwicklung Salzstress Tetrapyrrol-Biosynthese ALA-synthese Chlorophyll-katabolische Enzyme PSII-LHCII Superkomplexe ferrochelatase embryo development salt stress tetrapyrrole synthesis ALA synthesis chlorophyll catabolic enzymes PSII-LHCII supercomplexes 570 Biowissenschaften; Biologie ddc:570
20	Identification of the mechanisms of wild radish herbicide resistance to PSII inhibitors, auxinics, and AHAS inhibitors Friesen, Lincoln Jacob Shane January 2008 (has links) The objective of this Ph.D. research was to identify new and novel mechanisms of wild radish (Raphanus raphanistrum L.) resistance to photosystem II (PSII) inhibitors, auxinics, and acetohydroxyacid synthase (AHAS) inhibitors. PSIIinhibitor resistance was demonstrated to be target-site based, and conferred by a Ser264 to Gly substitution of the D1 protein. Auxinic resistance was associated with reduced herbicide translocation to the meristematic regions of resistant wild radish plants. Two new resistance mutations of wild radish AHAS were discovered, including one encoding the globally rare Asp376 to Glu substitution, and another encoding an Ala122 to Tyr substitution, which has never been identified or assessed for resistance in plants previously. Characterization of the frequency and distribution of AHAS resistance mutations in wild radish from the WA wheatbelt revealed that Glu376 was widespread, and that some mutations of AHAS are more common than others. Computer simulation was used to examine the molecular basis of resistance-endowing AHAS target-site mutations. Furthermore, through the computer-aided analysis, residues were identified with the potential to confer resistance upon substitution, but which have not previously been assessed for this possibility. Results from this Ph.D. research demonstrate that diverse, unrelated mechanisms of resistance to PSII inhibitors, auxinics, and AHAS inhibitors have evolved in wild radish of the WA wheatbelt, and that these mechanisms have accumulated in some populations. Radishes -- Control -- Western Australia Herbicide resistance Plants -- Effect of herbicides on AHAS/ALS inhibitor resistance Auxinic herbicide resistance PSII inhibitor resistance

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