Global ETD Search

21	Phytostabilisation : use of wetland plants to treat mine tailings Stoltz, Eva January 2004 (has links) Mine tailings can be rich in sulphide minerals and may form acid mine drainage (AMD) through reaction with atmospheric oxygen and water. AMD contains elevated levels of metals and arsenic (As) that could be harmful to animals and plants. An oxygen-consuming layer of organic material and plants on top of water-covered tailings would probably reduce oxygen penetration into the tailings and thus reduce the formation of AMD. However, wetland plants have the ability to release oxygen through the roots and could thereby increase the solubility of metals and As. These elements are released into the drainage water, taken up and accumulated in the plant roots, or translocated to the shoots. The aim was to examine the effects of plant establishment on water-covered mine tailings by answering following questions: A) Is plant establishment on water-covered mine tailings possible? B) What are the metal and As uptake and translocation properties of these plants? C) How do plants affect metal and As release from mine tailings, and which are the mechanisms involved? Carex rostrata Stokes, Eriophorum angustifolium Honck., E. scheuchzeri Hoppe, Phragmites australis (Cav.) Steud., Salix phylicifolia L. and S. borealis Fr. were used as test plants. Influences of plants on the release of As, Cd, Cu, Pb, Zn and in some cases Fe in the drainage water, and plant element uptake were studied in greenhouse experiments and in the field. The results obtained demonstrate that plant establishment are possible on water-covered unweathered mine tailings, and a suitable amendment was found to be sewage sludge. On acidic, weathered tailings, a pH increasing substance such as ashes should be added to improve plant establishment. The metal and As concentrations of the plant tissue were found to be generally higher in roots than in shoots. The uptake was dependent on the metal and As concentrations of the tailings and the release of organic acids from plant roots may have influenced the uptake. The metal release from tailings into the drainage water caused by E. angustifolium was found to depend greatly on the age and chemical properties of the tailings. However, no effects of E. angustifolium on As release was found. Water from old sulphide-, metal- and As-rich tailings with low buffering capacity were positively affected by E. angustifolium by causing higher pH and lower metal concentrations. In tailings with relatively low sulphide, metal and As contents combined with a low buffering capacity, plants had the opposite impact, i.e. a reduction in pH and elevated metal levels of the drainage water. The total release of metal and As from the tailings, i.e. drainage water together with the contents in shoots and roots, was found to be similar for C. rostrata, E. angustifolium and P. australis, except for Fe and As, where the release was highest for P. australis. The differences in metal and As release from mine tailings were mainly found to be due to the release of O2 from the roots, which changes the redox potential. Release of organic acids from the roots slightly decreased the pH, although did not have any particular influence on the release of metal and As. In conclusion, as shown here, phytostabilisation may be a successful technique for remediation of mine tailings with high element and sulphide levels, and low buffering capacity. Phytostabilisation wetland plants mine tailings Plant physiology Växtfysiologi
22	Phytoremediation of mercury by terrestrial plants Wang, Yaodong January 2004 (has links) Mercury (Hg) pollution is a global environmental problem. Numerous Hg-contaminated sites exist in the world and new techniques for remediation are urgently needed. Phytoremediation, use of plants to remove pollutants from the environment or to render them harmless, is considered as an environment-friendly method to remediate contaminated soil in-situ and has been applied for some other heavy metals. Whether this approach is suitable for remediation of Hg-contaminated soil is, however, an open question. The aim of this thesis was to study the fate of Hg in terrestrial plants (particularly the high biomass producing willow, Salix spp.) and thus to clarify the potential use of plants to remediate Hg-contaminated soils. Plants used for phytoremediation of Hg must tolerate Hg. A large variation (up to 30-fold difference) was detected among the six investigated clones of willow in their sensitivity to Hg as reflected in their empirical toxicity threshold (TT95b), the maximum unit toxicity (UTmax) and EC50 levels. This gives us a possibility to select Hg-tolerant willow clones to successfully grow in Hgcontaminated soils for phytoremediation. Release of Hg into air by plants is a concern when using phytoremediation in practice. No evidence was found in this study that Hg was released to the air via shoots of willow, garden pea (Pisum sativum L. cv Faenomen), spring wheat (Triticum aestivum L. cv Dragon), sugar beet (Beta vulgaris L. cv Monohill), oil-seed rape (Brassica napus L. cv Paroll) and white clover (Trifolium repens L.). Thus, we conclude that the Hg burden to the atmosphere via phytoremediation is not increased. Phytoremediation processes are based on the ability of plant roots to accumulate Hg and to translocate it to the shoots. Willow roots were shown to be able to efficiently accumulate Hg in hydroponics, however, no variation in the ability to accumulate was found among the eight willow clones using CVAAS to analyze Hg content in plants. The majority of the Hg accumulated remained in the roots and only 0.5-0.6% of the Hg accumulation was translocated to the shoots. Similar results were found for the five common cultivated plant species mentioned above. Moreover, the accumulation of Hg in willow was higher when being cultivated in methyl-Hg solution than in inorganic Hg solution, whereas the translocation of Hg to the shoots did not differ. The low bioavailability of Hg in contaminated soil is a restricting factor for the phytoextraction of Hg. A selected tolerant willow clone was used to study whether iodide addition could increase the plant-accumulation of Hg from contaminated soil. Both pot tests and field trials were carried out. Potassium iodide (KI) addition was found to mobilize Hg in contaminated soil and thus increase the bioavailability of Hg in soils. Addition of KI (0.2–1 mM) increased the Hg concentrations up to about 5, 3 and 8 times in the leaves, branches and roots, respectively. However, too high concentrations of KI were toxic to plants. As the majority of the Hg accumulated in the roots, it might be unrealistic to use willow for phytoextraction of Hg in practice, even though iodide could enhance the phytoextraction efficiency. In order to study the effect of willow on various soil fractions of Hg-contaminated soil, a 5-step sequential soil extraction method was used. Both the largest Hg-contaminated fractions, i.e. the Hg bound to residual organic matter (53%) and sulphides (43%), and the residual fraction (2.5%), were found to remain stable during cultivations of willow. The exchangeable Hg (0.1%) and the Hg bound to humic and fulvic acids (1.1%) decreased in the rhizospheric soil, whereas the plant accumulation of Hg increased with the cultivation time. The sum of the decrease of the two Hg fractions in soils was approximately equal to the amount of the Hg accumulated in plants. Consequently, plants may be suitable for phytostabilization of aged Hg-contaminated soil, in which root systems trap the bioavailable Hg and reduce the leakage of Hg from contaminated soils. phytoremediation phytoextraction phytostabilization bioavailability willow Hg Plant physiology Växtfysiologi
23	Low temperature acclimation in plants : alterations in photosynthetic carbon metabolism Lundmark, Maria January 2007 (has links) Although low temperature plays an important role in determining agricultural yield, little is known about the effect on the underlying biochemical and physiological processes that influence plant growth. Photosynthesis and respiration are central to plant growth and both processes are heavily affected by temperature. However, many plants have the ability to cope with low temperature and resume growth by cold acclimating. We have shown that enhancement of carbon fixation, an increased flux of carbon into sucrose and the recovery of diurnal export is crucial for the recovery of functional carbon metabolism at low temperature in Arabidopsis thaliana. The recovery of efflux is governed by increased expression of sucrose transporters along with changes in vascularisation. We also demonstrate the importance of controlling the flux of metabolites between the chloroplast and the cytosol by regulating the expression of AtTPT. We further investigated the difference in response between leaves developed at low temperature but originating from warm grown Arabidopsis and leaves from plants grown from seed at low temperature. We were able to distinguish factors that respond specifically to low temperature from those that are connected to the actual stress. Substantial difference could be seen in the different metabolomes. One conclusion drawn is that the increase in sucrose reported at low temperature is an essential feature for life in the cold. In an extended study we were able to transfer some of the key factor of cold acclimation in Arabidopsis to other species. The study included forbs, grasses and evergreen trees/shrubs showed that there are striking similarities in the extent and biochemical changes that underpin acclimation among the different functional groups. Low temperature does not only influence growth of the leaves, perennial organs such as the corm of the ornamental plant Crocus vernus is also affected. However in these plants low temperature has a positive effect on the final size of the corm. We were able to show that this enhanced growth was an affect of increased cell size and thus increased sink capacity, which ultimately delays leaf senescence Plant physiology cold acclimation carbon metabolism photosynthesis respiration Växtfysiologi
24	Photosynthetic water oxidation : the function of two extrinsic proteins Shutova, Tatiana January 2007 (has links) The solar energy accumulated by photosynthesis over billions of years is the sole source of energy available on Earth. Photosystem II (PSII) uses the sunlight to split water, an energetically unfavorable reaction where electrons and protons are extracted from water and oxygen is released as a by-product. Understanding this process is crucial for the future development of clean, renewable and unlimited energy sources, which can use sunlight to split water and produce hydrogen and electricity. In order to do so we need to understand how this is solved in plants. I have been focusing on the role of two lumenal proteins associated with the thylakoid membrane PsbO and Cah3, in the water oxidation process. Convincing evidences have been presented supporting the hypothesis that bicarbonate acts as a proton acceptor in the water splitting process in PSII and the lumenal carbonic anhydrase, Cah3, supplies bicarbonate required for this function. The PsbO protein, an important constituent of the water-oxidizing complex, however, its function is still unknown. The PsbO protein undergoes a pH dependent conformational change that in turn influences its capacity to bind calcium and manganese, forming a catalytic Mn4Ca cluster in PSII. We propose that light-induced structural dynamics of the PsbO is of functional relevance for the regulation of proton release and for forming a proton sensing - proton transporting pathway. The cluster of conserved glutamic and aspartic acid residues in the PsbO protein acts as buffering antennae providing efficient acceptors of protons derived from substrate water molecules. Both proteins, Cah3 and PsbO have a conserved S-S bridge, required for proper folding and activity; therefore they are potential targets for red-ox regulation in lumen. / Solenergi som omvandlats av fotosyntesen under miljarder av år är basen för nästan all energi på jorden. Fotosystem 2 använder solljuset till att oxidera vatten, ur energisynpunkt en ofördelaktig process, där elektroner och protoner extraheras från vattenmolekyler vilket ger upphov till syrgas som biprodukt. Förståelsen av denna process är viktig för att vi i framtiden skall kunna utveckla rena och förnyelsebara energislag i obegrensad mängd. Genom att efterlikna fotosyntesprocessen skulle vi i framtiden kunna utvecka artificiella system som använder solljuset till att sönderdela vatten för att producera vätgas eller elektrisitet. För att kunna göra det så måste vi kunna förstå hur dessa processer fungerar i växterna. Min forskning har fokuserat på att förstå funktionen hos två av de proteiner, PsbO och Cah3, som deltar i sönderdelningen av vatten. Jag har visat, för första gången, att ett lumen karboanhydras, Cah3, deltar i regleringen av den process där vatten spjälkas. Jag postulerar att Cah3 underlättar bort transporten av protoner från det vattenoxiderande komplexet genom att generera bikarbonat lokalt, som kan fungera som proton transportör. PsbO proteinet genomgår en pH beroende konformationsförändring vilket påverkar dess kapacitet and binda calcium och mangan som i sin tur formar ett katalytiskt Mn4Ca center i fotosystem 2. Jag föreslår att en ljusberoende strukturförändring av Psbo är av funktionell betydelse för regleringen av protonfrigörandet och formar ett proton-avkännande och proton-transporterande system. Ett kluster av konserverande glutamat- och aspartat-aminosyror i PsbO proteinet fungerar som ett buffrande nätverk för protoner som frigörs vid oxidering av vatten. Båda dessa proteiner innerhåller S-S bryggor ock kan därför vara red-ox reglerade i lumen. photosystem II Psb0 Cah3 water oxidation Plant physiology Växtfysiologi
25	Epigenetic Regulation of Light and Hormonal Signaling in Arabidopsis thaliana / Epigenetisk reglering av ljus och hormon signalering i Arabidopsis thaliana Rizzardi, Kristina January 2011 (has links) Plants are stationary and need to adapt to the environment they live in. Integration of environmental cues, such as changes in light and temperature, can occur either directly or through the action of hormones. Hormone and light signaling leads to rapid changes in gene expression, and eventually changes in protein levels. In this thesis I have studied how the epigenetic regulator TERMINAL FLOWER2 (TFL2) is involved in light and hormonal signaling in the model organism Arabidopsis thaliana (thale cress). TFL2 is the only Arabidopsis homologue of HETEROCHROMATIN PROTEIN1 (HP1). HP1 proteins have been shown to be involved in repressing gene expression by maintaining the tight structure of heterochromatin or by forming a heterochromatin like structure in euchromatic regions. Unlike metazoan HP1 which can be localized both to eu- and heterochromatin, TFL2 is uniquely localized to euchromatin. tfl2 mutants have reduced levels of free auxin and a reduced rate of auxin biosynthesis. TFL2 binds to and promotes spatial and temporal expression of the genes belonging to the YUCCA gene family, which are believed to regulate a rate limiting step in the auxin biosynthesis pathway. Further, TFL2 binds to a subset of Aux/IAA proteins to repress auxin regulated genes involved in ovule and carpel development. In a similar way, TFL2 is also involved in repressing two jasmonate responsive genes, VEGETATIVE STORAGE PROTEIN1 and 2. This TFL2 regulated repression might occur through the interaction with the jasmonate responsive protein JAZ6. In light signaling TFL2 is involved in repressing both phytochrome A and B signaling as the response to red and far red light is enhanced in tfl2 mutants. The shade avoidance response and chloroplast biogenesis are also regulated by TFL2 as the hypocotyls of tfl2 are not able to elongate as wt in shade conditions and greening is delayed upon de-etiolation of tfl2 seedlings. This work shows that TFL2 has a repressive function in auxin, jasmonate and light signaling and for the first time we show that TFL2 is directly involved in promoting gene expression. TERMINAL FLOWER2 auxin jasmonate epigenetics photomorphogenesis Plant physiology Växtfysiologi
26	Dissecting the photosystem II light-harvesting antenna Andersson, Jenny January 2003 (has links) <p>In photosynthesis, sunlight is converted into chemical energy that is stored mainly as carbohydrates and supplies basically all life on Earth with energy.</p><p>In order to efficiently absorb the light energy, plants have developed the outer light harvesting antenna, which is composed of ten different protein subunits (LHC) that bind chlorophyll a and b as well as different carotenoids. In addition to the light harvesting function, the antenna has the capacity to dissipate excess energy as heat (feedback de-excitation or qE), which is crucial to avoid oxidative damage under conditions of high excitation pressure. Another regulatory function in the antenna is the state transitions in which the distribution of the trimeric LHC II between photosystem I (PS I) and II is controlled. The same ten antenna proteins are conserved in all higher plants and based on evolutionary arguments this has led to the suggestion that each protein has a specific function.</p><p>I have investigated the functions of individual antenna proteins of PS II (Lhcb proteins) by antisense inhibition in the model plant Arabidopsis thaliana. Four antisense lines were obtained, in which the target proteins were reduced, in some cases beyond detection level, in other cases small amounts remained.</p><p>The results show that CP29 has a unique function as organising the antenna. CP26 can form trimers that substitute for Lhcb1 and Lhcb2 in the antenna structure, but the trimers that accumulate as a response to the lack of Lhcb1 and Lhcb2 cannot take over the LHC II function in state transitions. It has been argued that LHC II is essential for grana stacking, but antisense plants without Lhcb1 and Lhcb2 do form grana. Furthermore, LHC II is necessary to maintain growth rates in very low light.</p><p>Numerous biochemical evidences have suggested that CP29 and/or CP26 were crucial for feedback de-excitation. Analysis of two antisense lines each lacking one of these proteins clearly shows that there is no direct involvement of either CP29 or CP26 in this process. Investigation of the other antisense lines shows that no Lhcb protein is indispensable for qE. A model for feedback de-excitation is presented in which PsbS plays a major role.</p><p>The positions of the minor antenna proteins in the PS II supercomplex were established by comparisons of transmission electron micrographs of supercomplexes from the wild type and antisense plants.</p><p>A fitness experiment was conducted where the antisense plants were grown in the field and seed production was used to estimate the fitness of the different genotypes. Based on the results from this experiment it is concluded that each Lhcb protein is important, because all antisense lines show reduced fitness in the field.</p> Plant physiology antisense Arabidopsis thaliana chlorophyll carotenoid feedback de-excitation fitness LHC NPQ photosynthesis state transitions xanthophyll Växtfysiologi Plant physiology Växtfysiologi
27	Dissecting the photosystem II light-harvesting antenna Andersson, Jenny January 2003 (has links) In photosynthesis, sunlight is converted into chemical energy that is stored mainly as carbohydrates and supplies basically all life on Earth with energy. In order to efficiently absorb the light energy, plants have developed the outer light harvesting antenna, which is composed of ten different protein subunits (LHC) that bind chlorophyll a and b as well as different carotenoids. In addition to the light harvesting function, the antenna has the capacity to dissipate excess energy as heat (feedback de-excitation or qE), which is crucial to avoid oxidative damage under conditions of high excitation pressure. Another regulatory function in the antenna is the state transitions in which the distribution of the trimeric LHC II between photosystem I (PS I) and II is controlled. The same ten antenna proteins are conserved in all higher plants and based on evolutionary arguments this has led to the suggestion that each protein has a specific function. I have investigated the functions of individual antenna proteins of PS II (Lhcb proteins) by antisense inhibition in the model plant Arabidopsis thaliana. Four antisense lines were obtained, in which the target proteins were reduced, in some cases beyond detection level, in other cases small amounts remained. The results show that CP29 has a unique function as organising the antenna. CP26 can form trimers that substitute for Lhcb1 and Lhcb2 in the antenna structure, but the trimers that accumulate as a response to the lack of Lhcb1 and Lhcb2 cannot take over the LHC II function in state transitions. It has been argued that LHC II is essential for grana stacking, but antisense plants without Lhcb1 and Lhcb2 do form grana. Furthermore, LHC II is necessary to maintain growth rates in very low light. Numerous biochemical evidences have suggested that CP29 and/or CP26 were crucial for feedback de-excitation. Analysis of two antisense lines each lacking one of these proteins clearly shows that there is no direct involvement of either CP29 or CP26 in this process. Investigation of the other antisense lines shows that no Lhcb protein is indispensable for qE. A model for feedback de-excitation is presented in which PsbS plays a major role. The positions of the minor antenna proteins in the PS II supercomplex were established by comparisons of transmission electron micrographs of supercomplexes from the wild type and antisense plants. A fitness experiment was conducted where the antisense plants were grown in the field and seed production was used to estimate the fitness of the different genotypes. Based on the results from this experiment it is concluded that each Lhcb protein is important, because all antisense lines show reduced fitness in the field. Plant physiology antisense Arabidopsis thaliana chlorophyll carotenoid feedback de-excitation fitness LHC NPQ photosynthesis state transitions xanthophyll Växtfysiologi Plant physiology Växtfysiologi
28	Characterisation of the Clp Proteins in Arabidopsis thaliana Zheng, Bo January 2003 (has links) <p>Unlike in the greenhouse, plants need to cope with many environmental stresses under natural conditions. Among these conditions are drought, waterlogging, excessive or too little light, high or low temperatures, UV irradiation, high soil salinity, and nutrient deficiency. These stress factors can affect many biological processes, and severely retard the growth and development of higher plants, resulting in massive losses of crop yield and wood production. Plants have developed many protective mechanisms to survive and acclimate to stresses, such as the rapid induction of specific molecular chaperones and proteases at the molecular level. Molecular chaperones mediate the correct folding and assembly of polypeptides, as well as repair damaged protein structures caused by stress, while proteases remove otherwise non-functional and potentially cytotoxic proteins. </p><p>The Clp/Hsp100 family is a new group of chaperones that consists of both constitutive and stress-inducible members. Besides being important chaperones, many Clp/Hsp100 also participate in protein degradation by associating with the proteolytic subunit ClpP to form the Clp protease complex. Higher plants have the greatest number and complexity of Clp proteins than any other group of organisms, and more than 20 different Clp isomers in plants have been identified (Paper I). Because of this diversity, we have adopted a functional genomics approach to characterise all Clp proteins in the model plant Arabidopsis thaliana. Our ongoing research strategy combines genetic, biochemical and molecular approaches. Central to these has been the preparation of transgenic lines for each of the chloroplast Clp isomers. These transgenic lines will be analysed to understand the function and regulation of each chloroplast Clp protein for plant growth and development.</p><p>In Paper II, an Arabidopsis thaliana cDNA was isolated that encodes a homologue of bacterial ClpX. Specific polyclonal antibodies were made and used to localise the ClpX homologue to plant mitochondria, consistent with that predicted by computer analysis of the putative transit peptide. In addition to ClpX, a nuclear-encoded ClpP protein, termed ClpP2, was identified from the numerous ClpP isomers in Arabidopsis and was also located in mitochondria. Relatively unchanged levels of transcripts for both clpX and clpP2 genes were detected in various tissues and under different growth conditions. Using β-casein as a substrate, plant mitochondria possessed an ATP-stimulated, serine-type proteolytic activity that could be strongly inhibited by antibodies specific for ClpX or ClpP2, suggesting an active ClpXP protease.</p><p>In Paper III, four nuclear-encoded Clp isomers were identified in Arabidopsis thaliana: ClpC1 and ClpP3-5. All four proteins are localized within the stroma of chloroplasts, along with the previously identified ClpD, ClpP1 and ClpP6 proteins. Potential differential regulation among these Clp proteins was analysed at both the mRNA and protein level. A comparison between different tissues showed increasing amounts of all plastid Clp proteins from roots to stems to leaves. The increases in protein were mirrored at the mRNA level for most ClpP isomers but not for ClpC1, ClpC2 and ClpD and ClpP5, which exhibited little change in transcript levels. Potential stress induction was also tested for all chloroplast Clp proteins by a series of brief and prolonged stress conditions. The results reveal that these proteins, rather than being rapidly induced stress proteins, are primarily constitutive proteins that may also be involved in plant acclimation to different physiological conditions. </p><p>In Paper IV, antisense repression transgenic lines of clpP4 were prepared and then later characterised. Within the various lines screened, up to 90% of ClpP4 protein content was specifically repressed, which also led to the down-regulation of ClpP3 and ClpP5 protein contents. The repression of clpP4 mRNA retarded the development of chloroplasts and the differentiation of leaf mesophyll cells, resulting in chlorotic phenotypes. The chlorosis was more severe in young than in mature leaves due likely to the developmental expression pattern of the ClpP4 protein. Chlorotic plants eventually turned green upon aging, accompanied by a recovery in the amount of the ClpP4 protein. The greening process could be affected by the light quantity, either by altering the photoperiod or light intensity.</p> Plant physiology Arabidopsis molecular chaperone protein degradation protease Clp/Hsp100 ClpP stress response antisense repression chloroplast development Växtfysiologi Plant physiology Växtfysiologi
29	Characterisation of the Clp Proteins in Arabidopsis thaliana Zheng, Bo January 2003 (has links) Unlike in the greenhouse, plants need to cope with many environmental stresses under natural conditions. Among these conditions are drought, waterlogging, excessive or too little light, high or low temperatures, UV irradiation, high soil salinity, and nutrient deficiency. These stress factors can affect many biological processes, and severely retard the growth and development of higher plants, resulting in massive losses of crop yield and wood production. Plants have developed many protective mechanisms to survive and acclimate to stresses, such as the rapid induction of specific molecular chaperones and proteases at the molecular level. Molecular chaperones mediate the correct folding and assembly of polypeptides, as well as repair damaged protein structures caused by stress, while proteases remove otherwise non-functional and potentially cytotoxic proteins. The Clp/Hsp100 family is a new group of chaperones that consists of both constitutive and stress-inducible members. Besides being important chaperones, many Clp/Hsp100 also participate in protein degradation by associating with the proteolytic subunit ClpP to form the Clp protease complex. Higher plants have the greatest number and complexity of Clp proteins than any other group of organisms, and more than 20 different Clp isomers in plants have been identified (Paper I). Because of this diversity, we have adopted a functional genomics approach to characterise all Clp proteins in the model plant Arabidopsis thaliana. Our ongoing research strategy combines genetic, biochemical and molecular approaches. Central to these has been the preparation of transgenic lines for each of the chloroplast Clp isomers. These transgenic lines will be analysed to understand the function and regulation of each chloroplast Clp protein for plant growth and development. In Paper II, an Arabidopsis thaliana cDNA was isolated that encodes a homologue of bacterial ClpX. Specific polyclonal antibodies were made and used to localise the ClpX homologue to plant mitochondria, consistent with that predicted by computer analysis of the putative transit peptide. In addition to ClpX, a nuclear-encoded ClpP protein, termed ClpP2, was identified from the numerous ClpP isomers in Arabidopsis and was also located in mitochondria. Relatively unchanged levels of transcripts for both clpX and clpP2 genes were detected in various tissues and under different growth conditions. Using β-casein as a substrate, plant mitochondria possessed an ATP-stimulated, serine-type proteolytic activity that could be strongly inhibited by antibodies specific for ClpX or ClpP2, suggesting an active ClpXP protease. In Paper III, four nuclear-encoded Clp isomers were identified in Arabidopsis thaliana: ClpC1 and ClpP3-5. All four proteins are localized within the stroma of chloroplasts, along with the previously identified ClpD, ClpP1 and ClpP6 proteins. Potential differential regulation among these Clp proteins was analysed at both the mRNA and protein level. A comparison between different tissues showed increasing amounts of all plastid Clp proteins from roots to stems to leaves. The increases in protein were mirrored at the mRNA level for most ClpP isomers but not for ClpC1, ClpC2 and ClpD and ClpP5, which exhibited little change in transcript levels. Potential stress induction was also tested for all chloroplast Clp proteins by a series of brief and prolonged stress conditions. The results reveal that these proteins, rather than being rapidly induced stress proteins, are primarily constitutive proteins that may also be involved in plant acclimation to different physiological conditions. In Paper IV, antisense repression transgenic lines of clpP4 were prepared and then later characterised. Within the various lines screened, up to 90% of ClpP4 protein content was specifically repressed, which also led to the down-regulation of ClpP3 and ClpP5 protein contents. The repression of clpP4 mRNA retarded the development of chloroplasts and the differentiation of leaf mesophyll cells, resulting in chlorotic phenotypes. The chlorosis was more severe in young than in mature leaves due likely to the developmental expression pattern of the ClpP4 protein. Chlorotic plants eventually turned green upon aging, accompanied by a recovery in the amount of the ClpP4 protein. The greening process could be affected by the light quantity, either by altering the photoperiod or light intensity. Plant physiology Arabidopsis molecular chaperone protein degradation protease Clp/Hsp100 ClpP stress response antisense repression chloroplast development Växtfysiologi Plant physiology Växtfysiologi
30	Roles of LESIONS SIMULATING DISEASE1 and Salicylic Acid in Acclimation of Plants to Environmental Cues : Redox Homeostasis and physiological processes underlying plants responses to biotic and abiotic challenges Mateo, Alfonso January 2005 (has links) In the natural environment plants are confronted to a multitude of biotic and abiotic stress factors that must be perceived, transduced, integrated and signaled in order to achieve a successful acclimation that will secure survival and reproduction. Plants have to deal with excess excitation energy (EEE) when the amount of absorbed light energy is exceeding that needed for photosynthetic CO2 assimilation. EEE results in ROS formation and can be enhanced in low light intensities by changes in other environmental factors. The lesions simulating disease resistance (lsd1) mutant of Arabidopsis spontaneously initiates spreading lesions paralleled by ROS production in long day photoperiod and after application of salicylic acid (SA) and SA-analogues that trigger systemic acquired resistance (SAR). Moreover, the mutant fails to limit the boundaries of hypersensitive cell death (HR) after avirulent pathogen infection giving rise to the runaway cell death (rcd) phenotype. This ROS-dependent phenotype pointed towards a putative involvement of the ROS produced during photosynthesis in the initiation and spreading of the lesions. We report here that the rcd has a ROS-concentration dependent phenotype and that the light-triggered rcd is depending on the redox-state of the PQ pool in the chloroplast. Moreover, the lower stomatal conductance and catalase activity in the mutant suggested LSD1 was required for optimal gas exchange and ROS scavenging during EEE. Through this regulation, LSD1 can influence the effectiveness of photorespiration in dissipating EEE. Moreover, low and high SA levels are strictly correlated to lower and higher foliar H2O2 content, respectively. This implies an essential role of SA in regulating the redox homeostasis of the cell and suggests that SA could trigger rcd in lsd1 by inducing H2O2 production. LSD1 has been postulated to be a negative regulator of cell death acting as a ROS rheostat. Above a certain threshold, the pro-death pathway would operate leading to PCD. Our data suggest that LSD1 may be subjected to a turnover, enhanced in an oxidizing milieu and slowed down in a reducing environment that could reflect this ROS rheostat property. Finally, the two protein disulphide isomerase boxes (CGHC) present in the protein and the down regulation of the NADPH thioredoxin reductase (NTR) in the mutant connect the rcd to a putative impairment in the reduction of the cytosolic thioredoxin system. We propose that LSD1 suppresses the cell death processes through its control of the oxidation-reduction state of the TRX pool. An integrated model considers the role of LSD1 in both light acclimatory processes and in restricting pathogen-induced cell death. LSD1 Photooxidative stress Reactive oxygen species Light acclimation Photorespiration Salicylic acid Plant physiology Växtfysiologi

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