Biochemical and Molecular characterization of AtPAP25, a novel cell wall-localized purple acid phosphatase isozyme upregulated by phosphate-starved Arabidopsis thaliana

Del Vecchio, HERNAN

10 September 2012

Upregulation of intracellular and secreted acid phosphatases (APases) is a universal response of orthophosphate-starved (-Pi) plants. APases hydrolize Pi from a broad spectrum of phosphomonoesters at an acidic pH. Plant APases belong to a relatively large multigene family whose specific functions in Pi metabolism are poorly understood. This study focuses on the identification and characterization of cell wall (CW) localized purple acid APases (PAPs) upregulated by -Pi Arabidopsis thaliana. Three glycosylated PAP isozymes secreted into the CW of -Pi Arabidopsis suspension cells were purified and identified by peptide mass fingerprinting using mass spectrometry (MALDI-TOF MS) and N-terminal microsequencing as AtPAP12 (At2g27190; subunit size 60-kDa), AtPAP25 (At4g36350; subunit size 55-kDa) and AtPAP26 (At5g34850; subunit size 55-kDa). Both AtPAP12 and AtPAP26 were previously shown to be upregulated and secreted by –Pi Arabidopsis to scavenge Pi from extracellular organic-P. However, the novel AtPAP25 has never been suggested to be involved in the plant Pi-starvation response. Biochemical characterization of AtPAP25 revealed a monomeric 55 kDa protein. Similar to other PAPs it was purple-in-solution and insensitive to tartrate. Glycoprofiling via LC MS/MS revealed highly complex NXS/T glycosylation motifs at Asn172, Asn367 and Asn424. I hypothesize that these motifs play a role in AtPAP25 targeting and function. Kinetic characterization revealed a broad pH optimum centered at 5.6 and inhibition of activity by several common APase inhibitors. AtPAP25 exhibited broad substrate selectivity, low Vmax, and a Km (phosphoenolpyruvate) value of 0.52 mM. Immunoblot and semi-quantitative RT-PCR transcript analysis indicated that AtPAP25 is exclusively synthesized under –Pi conditions. Deduced amino acid sequences were compared using multiple sequence alignment and phylogenetic analysis. Growth of atpap25 T-DNA insertion mutant knockout seedlings was completely arrested when transferred to a soluble Pi deficient organic-P containing soil mix, pointing to a potential regulatory function of AtPAP25 during nutritional Pi stress. Overall, this research is helping to shed light on the functional importance of specific PAP isozymes in facilitating plant acclimation to nutritional Pi deficiency. This is important because there is an urgent need to engineer Pi-efficient transgenic crops to minimize the huge input of expensive, non-renewable, and polluting Pi fertilizers in agriculture. / Thesis (Master, Biology) -- Queen's University, 2012-09-10 08:28:21.631

Phosphate starvation alters calcium signalling in roots of Arabidopsis thaliana

Matthus, Elsa

January 2019

Low bioavailability of phosphate (P) due to low concentration and high immobility in soils is a key limiting factor in crop production. Application of excess amounts of P fertilizer is costly and by no means sustainable, as world-wide P resources are finite and running out. To facilitate the breeding of crops adapted to low-input soils, it is essential to understand the consequences of P deficiency. The second messenger calcium (Ca2+) is known to signal in plant development and stress perception, and most recently its direct role in signalling nutrient availability and deficiency has been partially elucidated. The use of Ca2+ as a signal has to be tightly controlled, as Ca2+ easily complexes with P groups and therefore is highly toxic to cellular P metabolism. It is unknown whether Ca2+ signals P availability or whether signalling is altered under P starvation conditions. The aim of this PhD project was to characterise the use of Ca2+ ions, particularly cytosolic free Ca2+ ([Ca2+]cyt), in stress signalling by P-starved roots of the model plant Arabidopsis thaliana. The hypothesis was that under P starvation and a resulting decreased cellular P pool, the use of [Ca2+]cyt may have to be restricted to avoid cytotoxic complexation of Ca2+ with limited P groups. Employing a range of genetically encoded Ca2+ reporters in Arabidopsis, P starvation but not nitrogen starvation was found to strongly dampen the root [Ca2+]cyt increases evoked by mechanical, salt, osmotic, and oxidative stress as well as by extracellular nucleotides. The strongly altered root [Ca2+]cyt response to extracellular nucleotides was shown to manifest itself during seedling development under chronic P deprivation, but could be reversed by P resupply. Fluorescent imaging elucidated that P-starved roots showed a normal [Ca2+]cyt response to extracellular nucleotides at the apex, but a strongly dampened [Ca2+]cyt response in distal parts of the root tip, correlating with high reactive oxygen species (ROS) levels induced by P starvation. Excluding iron, as well as P, rescued the altered [Ca2+]cyt response, and restored ROS levels to those seen under nutrient-replete conditions. P availability was not signalled through [Ca2+]cyt. In another part of this PhD project, a library of 77 putative Ca2+ channel mutants was compiled and screened for aberrant root hair growth under P starvation conditions. No mutant line showed aberrant root hair growth. These results indicate that P starvation strongly affects stress-induced [Ca2+]cyt modulations. The data generated in this thesis further understanding of how plants can integrate nutritional and environmental cues, adding another layer of complexity to the use of Ca2+ as a signal transducer.

Isolation and partial characterisation of PHT1;5, a putative high affinity phosphate transporter from Arabidopsis thaliana

Loedolff, Bianke

03 1900

Thesis (MSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Inorganic Phosphate (Pi) is one of the key nutrients required by all living organisms on earth. This nutrient is of vital importance to higher plants but it is not readily available for uptake from the soil, implying constant stress on plants. During photosynthetic dark and light reactions, phosphate is a prerequisite for all reactions to occur and to ensure plant survival. This statement implies that a careful homeostatic control of this nutrient is necessary in order to maintain a balanced carbon flow in all sub-cellular plant compartments. Phosphate limitation is a threat to plant survival and one way of addressing this nutritional hurdle is by feeding plants with fertilizer. This method of crop development and general plant maintenance by humans has a devastating effect on the environment, as phosphate causes eutrophication and various other consequences which are detrimental to animal life. Plants, however, are naturally equipped with Pi transporters which are activated conditionally depending on the external Pi availability. These transporters are present in most sub-cellular compartments and some of them have been identified and characterised, while others remain to be a prediction. If these transporters are characterised accordingly it might eventually mean that the use of fertilizers may no longer be necessary. In order to contribute to successful Pi-efficient crop development, a clearer understanding of P-dynamics in the soil and its recycling ability inside the plant itself is necessary. During this study it was attempted to characterise a putative high affinity Pi transporter, PHT1;5, from Arabidopsis thaliana via a Escherichia coli and yeast heterologous expression system and its Km value predicted in order to verify/hypothesise whether it is a high or low affinity transporter. This transporter is expressed in leaves and could be a promising tool for future carbon partitioning studies during phosphate limitation. / AFRIKAANSE OPSOMMING: Anorganiese fosfaat (Pi) word beskou as een van die belangrikste nutriente benodig vir alle lewe op aarde. Dit vervul ‘n hoof rol in talle noodsaaklike prosesse in hoër plante en is veral ‘n voorvereiste vir fotosintetiese reaksies om plaas te vind. In ‘n plant se natuurlike omgewing is anorganiese fosfaat nie geredelik bekskikbaar in grond nie en dus word daar vermoed dat plante onder konstante fosfaat stres gevind word. Omdat fosfaat so ‘n belangrike rol speel tydens fotosintese is dit noodsaaklik dat daar ‘n balans op sellulêre vlak gehandhaaf word, veral wat die verspreiding van koolhidrate tussen die verskillende kompartemente van die sel betref. Plante se oorlewing word bedreig deur ‘n tekort aan fosfaat in die omgewing en die enigste onmiddelike oplossing daarvoor is deur die toediening van bemestingstowwe. Hierdie metode van landery ontwikkeling en algemene instandhouding van plante deur die mensdom het ’n baie negatiewe effek op die omgewing. ‘n Oormaat fosfaat lei tot eutrifikasie en het verkeie ander negatiewe nagevolge wat dodelik is vir die dierelewe. Plante beskik ook oor natuurlike interne fosfaat transporters om hierdie tekort te oorkom. Hierdie transporters word op grond van eksterne fosfaat beskikbaarheid ge-aktiveer of ge-deaktifeer. Die transporters is teenwoordig in meeste sub-sellulêre kompartemente en sommige is al ge-identifiseer en gekarakteriseer, terwyl ander slegs ‘n voorspelling bly. Gedurende hierdie studie was ‘n poging aangewend om ‘n anorganiese fosfaat transporter van Arabidopsis thaliana, PHT1;5, te karakteriseer met behulp van mikro-organismes soos Escherichia coli en gis. Die poging het ingesluit om ‘n Km waarde vir hierdie transporter te voorspel en sodoende ‘n hipotese daar te stel van of dit hoë of lae affiniteit het vir fosfaat. Die transporter word groot en deels aangetref in blare en kan dus dien as ‘n belowende apparaat vir toekomstige koolhidraat uitruiling studies gedurende fosfaat tekort.

Phosphate transport

Phosphate nutrition

Phosphate utilisation

Phosphate starvation

Dissertations -- Plant biotechnology

Theses -- Plant biotechnology

Dissertations -- Genetics

Theses -- Genetics

Arabidopsis thaliana

Escherichia coli mutant strains

Impact des hydrocarbures aromatiques polycycliques sur le métabolisme lipidique et le transport du phosphore chez le champignon mycorhizien à arbuscules Rhizophagus irregularis / Polycyclic aromatic hydrocarbons impact on lipid metabolism and phosphorus transport in the arbuscular mycorrhizal fungus Rhizophagus irregularis

Calonne, Maryline

04 December 2012

Les hydrocarbures aromatiques polycyliques (HAPs) figurent parmi les polluants organiques persistants majeurs des sols pollués et présentent une toxicité avérée vis-à-vis de l'homme et des écosystèmes. Parmi les méthodes de remédiation des sols pollués par les HAPs, la phytoremédiation assistée par les champignons mycorhiziens à arbuscules (CMA), pourrait représenter une alternative innovante, écologique et économique. L'utilisation des mycorhizes comme outil de phytoremédiation des sols pollués présente plusieurs avantages dont une meilleure tolérance à la toxicité des HAPs, une meilleure nutrition hydrique et minérale ainsi qu'une meilleure dissipation des HAPs. De rares études ont décrit l'impact des HAPs sur le développement des CMA en lien avec une péroxydation lipidique et une perturbation des teneurs en lipides du CMA, mais ni les cibles d'action de ces polluants au niveau du métabolisme lipidique, ni le rôle de ces modifications dans sa tolérance aux HAPs et dans leur dissipation n'ont été étudiés. C'est pourquoi, le premier objectif de ce travail vise tout d'abord à comprendre l'impact des HAPs sur le métabolisme lipidique. Le radiomarquage par l'acétate [1-¹⁴C] a permis de montrer une perturbation de la biosynthèse des lipides membranaires du CMA extra-racinaire. D'autre part, nos résultats montrent que les HAPs affectent la nutrition phosphatée. Par ailleurs, la capacité des mycorhizes à dégrader et à bioaccumuler le benzo[a]pyrène est démontrée. Enfin, l'implication du métabolisme des lipides de réserve (les triacylglycérols) du mycélium extra-racinaire dans la régénération des membranes altérées, la lutte contre le stress oxydant induit par les HAPs et dans leur métabolisation/bioaccumulation est discutée. / Polycyclic aromatic hydrocarbons (PAHs) are among the major persistent organic pollutant frequently found in the polluted soils and are harmful for human health and its environment. To clean-up the PAHs polluted soils, phytoremediation assisted by arbuscular mycorrhizal fungi (AMF) could represent an innovative, ecological and cost-effective alternative. The use of mycorrhizas, as phytoremediation tool, has several advantages including increased tolerance to the pollutant toxicity, improved water and mineral nutrition as well as a better pollutant dissipation. Few studies have described the impact of PAHs on the AMF development related with lipid peroxidation and total lipid content disturbance. However, so far neither the target action of these pollutants on the metabolism, nor the role of these lipid changes in PAH tolerance and in their dissipation have been studied. Therefore, the present work aims firstly to improve our understanding of the PAHs impact on the CMA lipid metabolism. Thanks to radiolabeling experiments with [1-¹⁴C] acetate, our results showed a disruption of the membrane lipid biosynthesis pathways in the AMF extraradical mycelium, grown in the presence of PAHs. Secondly, it was highlighted that the PAHs affectef the phosphate nutrition. Finally, the mycorrhizas abilities to degrade and to bioaccumulate the benzo[a]pyrene, were pointed out. The involvement of extraradical mycelium storage lipid (triacyglycerols) metabolism in the membrane regeneration, the fight against the PAH induced-oxidative stress and the PAH metabolism/bioaccumulation is discussed.

Hydrocarbures Polycycliques Aromatiques

Champignon Micorhizien Arbusculaire

Phytoremédiation

Métabolisme lipidique

Nutrition phosphatée

Benzo[a]pyrène dégradation

Culture in vitro

Ecotoxicité

Polycyclic aromatic hydrocarbons

Arbuscular mycorrhizal fungus

Phytoremediation

Lipid metabolism

Phosphate nutrition

Benzo[a]pyrene degradation

In vitro cultures

Rhizophagus irregularis

Ecotoxicity