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The evolutionary success of higher plants is largely attributed to their tremendous developmental
plasticity, which allows them to cope with adverse conditions. However, because these adaptations
require investments of resources, they must be tightly regulated to avoid unfavourable trade-offs.
Most of the resources required are macronutrients based on carbon and nitrogen. Limitations in the
availability of these nutrients have major effects on gene expression, metabolism, and overall plant
morphology. These changes are largely mediated by the highly conserved master kinase SNF1-RELATED
PROTEIN KINASE1 (SnRK1), which represses growth and induces catabolic processes. Downstream of
SnRK1, a hub of heterodimerising group C and S1 BASIC LEUCINE ZIPPER (bZIP) transcription factors has
been identified. These bZIPs act as regulators of nutrient homeostasis and are highly expressed in
strong sink tissues, such as flowers or the meristems that initiate lateral growth of both shoots and
roots. However, their potential involvement in controlling developmental responses through their
impact on resource allocation and usage has been largely neglected so far. Therefore, the objective of
this work was to elucidate the impact of particularly S1 bZIPs on gene expression, metabolism, and
plant development.
Due to the high homology and suspected partial redundancy of S1 bZIPs, higher order loss-of-function
mutants were generated using CRISPR-Cas9. The triple mutant bzip2/11/44 showed a variety of robust
morphological changes but maintained an overall growth comparable to wildtype plants. In detail
however, seedlings exhibited a strong reduction in primary root length. In addition, floral transition
was delayed, and siliques and seeds were smaller, indicating a reduced supply of resources to the shoot
and root apices. However, lateral root density and axillary shoot branching were increased, suggesting
an increased ratio of lateral to apical growth in the mutant. The full group S1 knockout
bzip1/2/11/44/53 showed similar phenotypes, albeit far more pronounced and accompanied by
growth retardation. Metabolomic approaches revealed that these architectural changes were
accompanied by reduced sugar levels in distal sink tissues such as flowers and roots. Sugar levels were
also diminished in leaf apoplasts, indicating that long distance transport of sugars by apoplastic phloem
loading was impaired in the mutants. In contrast, an increased sugar supply to the proximal axillary
buds and elevated starch levels in the leaves were measured. In addition, free amino acid levels were
increased in bzip2/11/44 and bzip1/2/11/44/53, especially for the important transport forms
asparagine and glutamine. The increased C and N availability in the proximal tissues could be the cause
of the increased axillary branching in the mutants.
To identify bZIP target genes that might cause the observed shifts in metabolic status, RNAseq
experiments were performed. Strikingly, clade III SUGARS WILL EVENTUALLY BE EXPORTED (SWEET)
8
genes were abundant among the differentially expressed genes. As SWEETs are crucial for sugar export
to the apoplast and long-distance transport through the phloem, their reduced expression is likely to
be the cause of the observed changes in sugar allocation. Similarly, the reduced expression of
GLUTAMINE AMIDOTRANSFERASE 1_2.1 (GAT1_2.1), which exhibits glutaminase activity, could be an
explanation for the abundance of glutamine in the mutants. Additional experiments (ATAC-seq, DAPseq, PTA, q-RT-PCR) supported the direct induction of SWEETs and GAT1_2.1 by S1 bZIPs. To confirm
the involvement of these target genes in the observed S1 bZIP mutant phenotypes, loss-of-function
mutants were obtained, which showed moderately increased axillary branching. At the same time, the
induced overexpression of bZIP11 in axillary meristems had the opposite effect.
Collectively, a model is proposed for the function of S1 bZIPs in regulating sink tissue development. For
efficient long-distance sugar transport, bZIPs may be required to induce the expression of clade III
SWEETs. Thus, reduced SWEET expression in the S1 bZIP mutants would lead to a decrease in apoplastic
sugar loading and a reduced supply to distal sinks such as shoot or root apices. The reduction in longdistance transport could lead to sugar accumulation in the leaves, which would then increasingly be
transported via symplastic routes towards proximal sinks such as axillary branches and lateral roots or
sequestered as starch. The reduced GAT1_2.1 levels lead to an abundance of glutamine, a major
nitrogen transport form. The combined effect on C and N allocation results in increased nutrient
availability in proximal tissues, promoting the formation of lateral plant organs. Alongside emerging
evidence highlighting the power of bZIPs to steer nutrient allocation in other species, a novel but
evolutionary conserved role for S1 bZIPs as regulators of developmental plasticity is proposed, while
the generation of valuable data sets and novel genetic resources will help to gain a deeper
understanding of the molecular mechanisms involved
Sphingolipid long-chain bases (LCBs) are the building blocks of the biosynthesis of sphingolipids. They
are defined as structural elements of the plant cell membrane and play an important role
determining the fate of the cells. Complex ceramides represent a substantial fraction of total
sphingolipids which form a major part of eukaryotic membranes. At the same time, LCBs are well
known signaling molecules of cellular processes in eukaryotes and are involved in signal transduction
pathways in plants. High levels of LCBS have been shown to be associated with the induction of
programmed cell death as well as pathogen-derived toxin-induced cell death. Indeed, several studies
confirmed the regulatory function of sphingobases in plant programmed cell death (PCD):
(i) Spontaneous PCD and altered cell death reaction caused by mutated related genes of sphingobase
metabolism. (ii) Cell death conditions increases levels of LCBs. (iii) PCD due to interfered sphingolipid
metabolism provoked by toxins produced from necrotrophic pathogens, such as Fumonisin B1 (FB1).
Therefore, to prevent cell death and control cell death reaction, the regulation of levels of free LCBs
can be crucial.
The results of the present study challenged the comprehension of sphingobases and sphingolipid
levels during PCD. We provided detailed analysis of sphingolipids levels that revealed correlations of
certain sphingolipid species with cell death. Moreover, the investigation of sphingolipid biosynthesis
allowed us to understand the flux after the accumulation of high LCB levels. However, further
analysis of degradation products or sphingolipid mutant lines, would be required to fully understand
how high levels of sphingobases are being treated by the plant.
Understanding the causal relationship between genotype and phenotype is a major objective in biology. The main interest is in understanding trait architecture and identifying loci contributing to the respective traits. Genome-wide association mapping (GWAS) is one tool to elucidate these relationships and has been successfully used in many different species. However, most studies concentrate on marginal marker effects and ignore epistatic and gene-environment interactions. These interactions are problematic to account for, but are likely to make major contributions to many phenotypes that are not regulated by independent genetic effects, but by more sophisticated gene-regulatory networks. Further complication arises from the fact that these networks vary in different natural accessions. However, understanding the differences of gene regulatory networks and gene-gene interactions is crucial to conceive trait architecture and predict phenotypes.
The basic subject of this study – using data from the Arabidopsis 1001 Genomes Project – is the analysis of pre-mature stop codons. These have been incurred in nearly one-third of the ~ 30k genes. A gene-gene interaction network of the co-occurrence of stop codons has been built and the over and under representation of different pairs has been statistically analyzed. To further classify the significant over and under- represented gene-gene interactions in terms of molecular function of the encoded proteins, gene ontology terms (GO-SLIM) have been applied. Furthermore, co- expression analysis specifies gene clusters that co-occur over different genetic and phenotypic backgrounds. To link these patterns to evolutionary constrains, spatial location of the respective alleles have been analyzed as well. The latter shows clear patterns for certain gene pairs that indicate differential selection.
The phytohormone auxin performs important functions in the initiation of plant tissues and organs, as well as in the control of root growth in conjunction with external stimuli such as gravity, water and nutrient availability. These functions are based primarily on the auxin-dependent regulation of cell division and elongation. Important for the latter is the control of the cell turgor by the vacuole. As storage for nutrients, metabolites and toxins, vacuoles are of vital importance. Vacuolar stored metabolites and ions are exchanged across the vacuolar membrane with the cytoplasm via active transport processes as well as passively through ion channels. In their function as second messenger, calcium ions are important regulators but also subject to vacuolar transport processes. Changes in the cytosolic calcium concentration not only act locally, but are also associated with signal transduction over longer distances. In this work, electrophysiological methods were combined with imaging techniques to gain insights into the interaction between cytosolic calcium signals, vacuolar transport processes and auxin physiology in the intact plant organism.
Calcium signals are involved in the regulation of vacuolar ion channels and transporters. In order to investigate this in the intact organism, intracellular microelectrode measurements were performed in the model system of bulging Arabidopsis thaliana root hairs. By means of the two-electrode voltage-clamp technique, it could be confirmed that the vacuolar membrane is the limiting electrical resistance during intravacuolar measurements and thus measured ion currents actually represent only the currents across the vacuolar membrane. The already known time-dependent decrease of vacuolar conductivity during intravacuolar experiments could be further correlated with an impalement-related, transient increase of the cytosolic calcium concentration. Intravacuolar voltage-clamp experiments in root hair cells of calcium reporter plants confirmed this relationship between vacuolar conductivity and the cytosolic calcium concentration.
However, the vacuole is not just a recipient of cytosolic calcium signals. Since the vacuole represents the largest intracellular calcium reservoir, it has long been argued that it is also involved in the generation of such signals. This could be confirmed in intact root hair cells. Changes in the vacuolar membrane potential affected the cytosolic calcium concentration in these cells. While depolarizing potentials led to an increase of the cytosolic calcium concentration, hyperpolarization of the vacuolar membrane caused the opposite. Thermodynamic considerations of passive and active calcium transport across the vacuolar membrane suggested that the results described herein reflect the behaviour of vacuolar H+/Ca2+ exchangers whose activity is determined by the proton motive force.
In addition, cytosolic calcium has been shown to be a key regulator of a rapid auxin-induced signaling pathway that regulates polar transport of the hormone.
In the same model system of bulging root hairs it could be shown that the external application of auxin results in a very fast, auxin concentration- and pH-dependent depolarization of the plasma membrane potential. Synchronous with the depolarization of the plasma membrane potential, transient calcium signals were recorded in the cytosol. These were caused by an auxin-activated influx of calcium ions through the ion channel CNGC14. Experiments on loss-of-function mutants as well as pharmacological experiments showed that the auxin-induced activation of the calcium channel requires auxin-perception by the F-box proteins of the TIR1/AFB family.
Investigations of auxin-dependent depolarization as well as the auxin-induced influx of protons into epidermal root cells of loss-of-function mutants showed that the secondary active uptake of auxin by the high-affinity transport protein AUX1 is responsible for the rapid depolarization
Not only the cytosolic calcium signals correlated with CNGC14 function, but also the AUX1-mediated depolarization of root hairs. An unchanged expression of AUX1 in the cngc14 loss-of-function mutant suggested that the activity of AUX1 must be post-translationally regulated. This hypothesis was supported by experiments in which treatment with the calcium channel blocker lanthanum led to inactivation of AUX1 in the wild type.
The cytosolic loading of individual epidermal root cells with auxin resulted in the spread of lateral and acropetal calcium waves. These correlated with a shift of the auxin gradient at the root apex and thus supported a hypothetical calcium-dependent regulation of polar auxin transport. A model for a rapid, auxin-induced and calcium-dependent signaling pathway is presented and its importance for gravitropic root growth is discussed. Since AUX1-mediated depolarization varied with external phosphate concentration, the importance of this rapid signaling pathway is also discussed for the adaptation of root hair growth to an inadequate availability of phosphate.
The control of energy homeostasis is of pivotal importance for all living organisms. In the last years emerged the idea that many stress responses that are apparently unrelated, are actually united by a common increase of the cellular energy demand. Therefore, the so called energy signaling is activated by many kind of stresses and is responsible for the activation of the general stress response. In Arabidopsis thaliana the protein family SnF1- related protein kinases (SnRK1) is involved in the regulation of many physiological processes but is more known for its involvement in the regulation of the energy homeostasis in response to various stresses. To the SnRK1 protein family belong SnRK1.1 (also known as KIN10), SnRK1.2 (KIN11), and SnRK1.3 (KIN12). SnRK1 exerts its function regulating directly the activity of metabolic enzymes or those of key transcription factors (TFs). The only TFs regulated by SnRK1 identified so far is the basic leucine zipper (bZIP) 63. bZIP63 belongs to the C group of bZIPs (C-bZIPs) protein family together with bZIP9, bZIP10, and bZIP25. SnRK1.1 phosphorylates bZIP63 on three amino acids residues, serine (S) 29, S294, and S300. The phosphorylation of tbZIP63 is strongly related to the energy status of the plant, shifting from almost absent during the normal growth to strongly phosphorylated when the plant is exposed to extended dark. bZIPs normally bind the DNA as dimer in order to regulate the expression of their target genes. C-bZIPs preferentially form dimers with S1-bZIPs, constituting the so called C/S1- bZIPs network. The SnRk1 dependent phosphorylation of bZIP63 regulates its activation potential and its dimerization properties. In particular bZIP63 shift its dimerization preferences according to its phosphorylation status. The non-phosphorylated form of bZIP63 dimerize bZIP1, the phosphorylates ones, instead, forms dimer with bZIP1, bZIP11, and bZIP63 its self. Together with bZIP63, S1-bZIPs are important mediator of part of the huge transcriptional reprogramming induced by SnRK1 in response to extended dark. S1-bZIPs regulate, indeed, the expression of 4'000 of the 10'000 SnRK1-regulated genes in response to energy deprivation. In particular S1-bZIPs are very important for the regulation of many genes encoding for enzymes involved in the amino acid metabolism and for their use as alternative energy source. After the exposition for some hours to extended dark, indeed, the plant make use of every energy substrate and amino acids are considered an important energy source together with lipids and proteins. Interestingly, S1- bZIPs regulate the expression of ETFQO. ETFQO is a unique protein that convoglia the electrons provenienti from the branch chain amino acids catabolism into the mitochondrial electron transport chain. The dimer formed between bZIP63 and bZIP2 recruits SnRK1.1 directly on the chromatin of ETFQO promoter. The recruitment of SnRK1 on ETFQO promoter is associated with its acetylation on the lysine 14 of the histone protein 3 (K14H3). This chromatin modification is normally asociated with an euchromatic status of the DNA and therefore with its transcriptional activation. Beside the particular case of the regulation of ETFQO gene, S1-bZIPs are involved in the regulation of many other genes activated in response of different stresses. bZIP1 is for example an important mediator of the salt stress response. In particular bZIP1 regulates the primary C- and N-metabolism. The expression of bZIP1, in response of both salt ans energy stress seems to be regulated by SnRK1, as it is the expression of bZIP53 and bZIP63.
Beside its involvement in the regulation of the energy stress response and salt response, SnRK1 is the primary activators of the lipids metabolism during see germination. SnRK1, indeed, controls the expression of CALEOSINs and OLEOSINs. Those proteins are very important for lipids remobilization from oil droplets. Without their expression seed germination and subsequent establishment do not take place because of the absence of fuel to sustain these highly energy costly processes, which entirely depend on the catabolism of seed storages.
Host–microbe interactions are the key to understand why and how microbes inhabit specific environments. With the scientific fields of microbial genomics and metagenomics, evolving on an unprecedented scale, one is able to gain insights in these interactions on a molecular and ecological level. The goal of this PhD thesis was to make (meta–)genomic data accessible, integrate it in a comparative manner and to gain comprehensive taxonomic and functional insights into bacterial strains and communities derived from two different environments: the phyllosphere of Arabidopsis thaliana and the mesohyl interior of marine sponges.
This thesis focused first on the de novo assembly of bacterial genomes. A 5–step protocol was developed, each step including a quality control. The examination of different assembly software in a comparative way identified SPAdes as most suitable. The protocol enables the user to chose the best tailored assembly. Contamination issues were solved by an initial filtering of the data and methods normally used for the binning of metagenomic datasets. This step is missed in many published assembly pipelines. The described protocol offers assemblies of high quality ready for downstream analysis.
Subsequently, assemblies generated with the developed protocol were annotated and explored
in terms of their function. In a first study, the genome of a phyllosphere bacterium, Williamsia sp. ARP1, was analyzed, offering many adaptions to the leaf habitat: it can deal with temperature shifts, react to oxygen species, produces mycosporins as protection against UV–light, and is able to uptake photosynthates. Further, its taxonomic position within the Actinomycetales was infered from 16S rRNA and comparative genomics showing the close relation between the genera Williamsia and Gordonia.
In a second study, six sponge–derived actinomycete genomes were investigated for secondary metabolism. By use of state–of–the–art software, these strains exhibited numerous gene clusters, mostly linked to polykethide synthases, non–ribosomal peptide synthesis, terpenes, fatty acids and saccharides. Subsequent predictions on these clusters offered a great variety of possible produced compounds with antibiotic, antifungal or anti–cancer activity. These analysis highlight the potential for the synthesis of natural products and the use of genomic data as screening toolkit.
In a last study, three sponge–derived and one seawater metagenomes were functionally compared. Different signatures regarding the microbial composition and GC–distribution were observed between the two environments. With a focus on bacerial defense systems, the data indicates a pronounced repertoire of sponge associated bacteria for bacterial defense systems, in particular, Clustered Regularly Interspaced Short Palindromic Repeats, restriction modification system, DNA phosphorothioation and phage growth limitation. In addition, characterizing genes for secondary metabolite cluster differed between sponge and seawater microbiomes. Moreover, a variety of Type I polyketide synthases were only found within the sponge microbiomes. With that, metagenomics are shown to be a useful tool for the screening of secondary metabolite genes. Furthermore, enriched defense systems are highlighted as feature of sponge-associated microbes and marks them as a selective trait.
Plants are exposed to high temperature, especially during hot summer days. Temperatures are typically lowest in the morning and reach a maximum in the afternoon. Plants can tolerate and survive short-term heat stress even on hot summer days. A. thaliana seedlings have been reported to tolerate higher temperatures for different time periods, a phenomenon that has been termed basal thermotolerance. In addition, plants have the inherent capacity to acclimate to otherwise lethal temperatures. Arabidopsis thaliana seedlings acclimate at moderately elevated temperatures between 32–38° C. During heat acclimation, a genetically programmed heat shock response (HSR) is triggered that is characterized by a rapid activation of heat shock transcription factors (HSFs), which trigger a massive accumulation of heat shock proteins that are chiefly involved in protein folding and protection.
Although the HSF-triggered heat-shock response is well characterized, little is known about the metabolic adjustments during heat stress. The aim of this work was to get more insight into heat-responsive metabolism and its importance for thermotolerance.
In order to identify the response of metabolites to elevated temperatures, global metabolite profiles of heat-acclimated and control seedlings were compared. Untargeted metabolite analyses revealed that levels of polyunsaturated triacylglycerols (TG) rapidly increase during heat acclimation. TG accumulation was found to be temperature-dependent in a temperature range from 32–50° C (optimum at 42° C). Heat-induced TG accumulation was localized in extra-chloroplastic compartments by chloroplast isolation as well as by fluorescence microscopy of A. thaliana cell cultures.
Analysis of mutants deficient in all four HSFA1 master regulator genes or the HSFA2 gene revealed that TG accumulation occurred independently to HSF. Moreover, the TG response was not limited to heat stress since drought and salt stress (but not short-term osmotic, cold and high light stress) also triggered an accumulation of TGs.
In order to reveal the origin of TG synthesis, lipid analysis was carried out. Heat-induced accumulation of TGs does not derive from massive de novo fatty acid (FA) synthesis. On the other hand, lipidomic analyses of A. thaliana seedlings indicated that polyunsaturated FA from thylakoid galactolipids are incorporated into cytosolic TGs during heat stress. This was verified by lipidomic analyses of A. thaliana fad7/8 transgenic seedlings, which displayed altered FA compositions of plastidic lipids. In addition, wild type A. thaliana seedlings displayed a rapid conversion of plastidic monogalactosyldiacylglycerols (MGDGs) into oligogalactolipids, acylated MGDGs and diacylglycerols (DGs). For TG synthesis, DG requires a FA from the acyl CoA pool or phosphatidylcholine (PC). Seedlings deficient in phospholipid:diacylglycerol acyltransferase1 (PDAT1) were unable to accumulate TGs following heat stress; thus PC appears to be the major FA donor for TGs during heat treatment. These results suggest that TG and oligogalactolipid accumulation during heat stress is driven by post-translationally regulated plastid lipid metabolism.
TG accumulation following heat stress was found to increase basal thermotolerance. Pdat1 mutant seedlings were more sensitive to severe heat stress without prior acclimatization, as revealed by a more dramatic decline of the maximum efficiency of PSII and lower survival rate compared to wild type seedlings. In contrast, tgd1 mutants over-accumulating TGs and oligogalactolipids displayed a higher basal thermotolerance compared to wild type seedlings. These results therefore suggest that accumulation of TGs increases thermotolerance in addition to the genetically encoded heat shock response.
Physiological Role of Fatty Acid Desaturation in Agrobacterium-induced Arabidopsis Crown Galls
(2011)
Crown gall development is accompanied by hypoxia, drought and oxidative stress. These abiotic stress factors are known to have an impact on fatty acid (FA) desaturation. Thus, an alteration in the lipid profile of plant tumors was expected. A comprehensive lipid analysis of Arabidopsis thaliana crown galls induced by Agrobacterium tumefaciens showed an increase in the degree of FA desaturation. The poly unsaturated fatty acid (PUFA) linolenic acid (18:3) of endoplasmic reticulum (ER) derived phospholipids was especially affected. The increased levels of desaturated FAs were reflected by a strong induction of two genes encoding desaturases, FAD3 and SAD6. In contrast to FAD3, which encodes the ER membrane bound fatty acid desaturase enzyme that synthesizes 18:3 PUFAs in the ER, the function of SAD6 is unknown. The ability of SAD6 to complement the extreme dwarf growth phenotype of the ssi2-2 mutant allele suggests that SAD6 is a functional stearoyl-acyl-carrier-protein delta-9 desaturase (SAD) which catalyzes the first step in FA desaturation and forms stearic acid (18:1). Overexpression of the SAD6 gene in Arabidopsis (SAD6-OE) to a similar degree as in tumors resulted in a light-dependent chlorosis phenotype and caused a similar shift in the lipid profile towards unsaturated phospholipids. Posttranscriptional down-regulation of SAD6 overexpression by RNA reverted the chlorosis phenotype and the changes in the lipid profile, showing that SAD6 overexpression forms the unsaturated FA profile and the phenotype in SAD6-OE. The subcellular localization of the SAD6 protein in chloroplasts, which is obligatory for SAD function was demonstrated. SSI2, which encodes the major contributor to the 18:1 FA levels in Arabidopsis is down-regulated in crown galls pointing to a replacement of SSI2 function by SAD6 in the tumor. SAD6 transcripts were almost undetectable in Arabidopsis under normal growth condition, whereas under hypoxia the gene was strongly activated. In the tumor hypoxia most likely caused the very high transcription of SAD6. Hypoxia is known to limit FA desaturation and it is associated with an elevated reactive oxygen species (ROS) production which is detrimental for unsaturated FAs. Thus, up-regulation of SAD6 in the crown gall, most likely serves as an adaptive mechanism to activate desaturation under low oxygen concentrations and to maintain the levels of unsaturated FA under oxidative stress. The ER localized FAD3 most likely is responsible for the rise in 18:3 of the phospholipid class to cope with drought stress in crown galls. This hypothesis was supported by the loss of function mutant, fad3-2, which developed significantly smaller tumors as the wild type under low relative humidity.Taken together, this study suggests that the induction of SAD6 and FAD3 shapes the tumor lipid profile by increasing the levels of unsaturated FAs. Unsaturated fatty acids prepare the crown gall to cope with ongoing hypoxia, drought and oxidative stress during growth and development.
The present study was aimed at revealing the early signalling events during the interaction of the diazotrophic soil bacterium Azospirillum brasilense with its host plant Arabidopsis thaliana. Furthermore, taking advantage of the micro array technique, a comprehensive overview of Arabidopsis genes has been undertaken which are affected upon association with A. brasilense The characterization of the early responses of Arabidopsis plants upon inoculation with Azospirillum brasilense strain Sp7 clearly indicated parallels with the initial events in plant pathogen interaction. For instance, not only bacterial preprations (lysates) form Azospirillum elicited an apoplastic alkalinization of the culture medium, but also the live bacteria, which were even more effective. Besides, in a luminol based assay, the bacterial lysates triggered production of the reactive oxygen species (ROS) in the Arabidopsis leaf discs. Interestingly, the elongation factor receptor mutants (efr) were completely insensitive to Azospirillum, suggesting elongation factor Tu (EF-TU) recognition as elicitor by Arabidopsis. This hypothesis was further validated with a bioinformatic approach. The N terminus initial 26 amino acids from Azospirillum EF-TU gene (elf26) showed more similarity to the elf26 sequences of bacteria like Agrobacterium tumefaciens which elicit responses in the plants through EF-TU rather than Pseudomonas syringae where the potent elicitor is flagellin 22. Universal transcriptome profiling of Arabidopsis thaliana seedlings upon inoculation with Azospirillum brasilense over a time course of six, twenty four and ninty six hours revealed very little genetic responses in the early time points. However, a bulk of genes was differentially regulated in 96 hours post inoculation (96hpi). The nature of these genes indicated that the bacterial treatment, among others, greatly affect the processes like cell wall modification, hormone metabolism, stress and secondary metabolism. Additionally expression levels of a numer of transcription factors (TFs) related to basic helix loop helix (BHLH) and MYB domain containing TF families were altered with Azospirillum inoculation. Particularly the BHLH TFs were among the most highly regulated genes. The array results from Azospirillum treated plants were further compared with the already available data emnating from treatment with flagellin 22 (flg22), oligogalacturonides (OGs) and Agrobacterium tumefaciens. Noteworthy, very different set of genes were affected upon inoculation with Azospirillum in relation to other treatments. Secondly a cluster of proteins involved in the biosynthesis of aliphatic glucosinolates (GSL) were uniquely induced upon Sp7 exposure. Genes operating in flavonoid biosynthesis also showed a distinct regulation trend in the comparative analysis. Taken together, the study in question provides insights into the early signalling events in the context of Azospirillum-Arabidopsis association and the bacterial signals recognized by the plants. The array data, at the same time, elucidates the genetic factors of Arabidopsis triggered upon association with Azospirillum brasilense.
Arabidopsis thaliana (A.th.) mesophyll cells play a pivotal role in the regulation of the drought stress response. The signaling & transport components involved in drought stress regulation within lipid rafts of the plasma membrane were investigated by DRM isolation from highly purified plasma membranes. Detergent treatment with Brij-98 and Triton X-100 resulted in a total of 246 DRM proteins which were identified by nano HPLC-MS/MS. The majority of these proteins could be isolated by Triton X-100 treatment (78.5 %) which remains the ”golden” standard for the isolation of DRMs. Comparing in-gel and in-solution digestion approaches disclosed additional protein identifications for each method but the in-gel approach clearly delivered the majority of the identified proteins (81.8 %). Functionally, a clear bias on signaling proteins was visible – almost 1/3 of the detected DRM proteins belonged to the group of kinases, phosphatases and other signaling proteins. Especially leucine-rich repeat receptor-like protein kinases and calcium-dependent protein kinases were present in Brij-98 & Triton X-100 DRMs, for instance the calcium-dependent protein kinase CPK21. Another prominent member of DRMs was the protein phosphatase 2C 56, ABI1, which is a key regulator of the ABA-mediated drought stress response in A.th. The lipid raft localization of the identified DRM proteins was confirmed by sterol-depletion with the chemical drug MCD. Proteins which depend upon a sterol-rich environment are depleted from DRMs by MCD application. Especially signaling proteins exhibited a strong sterol-dependency. They represented the vast majority (41.5 %) among the Triton X-100 DRM proteins which were no longer detected following MCD treatment. AtRem 1.2 & 1.3 could be shown to be sterol-dependent in mesophyll cells as well as two CPKs (CPK10 & CPK21) and the protein phosphatase ABI1. AtRem 1.2 & 1.3 could be proven to represent ideal plant lipid raft marker proteins due to their strong presence in Triton X-100 DRMs and dependency upon a sterol-rich environment. When fluorescence labeled AtRem 1.2 & 1.3 were transiently expressed in A.th. leaves, they localized to small, patchy structures at the plasma membrane. CPK21 was an intrinsic member of Triton X-100 DRMs and displayed extreme susceptibility to sterol-depletion by MCD in immunological and proteomic assays. Calcium-dependent protein kinases (CPKs) have already been studied to be involved in drought stress regulation, for instance at the regulation of S-type anion channels in guard cells. Hence, further transient expression studies with the anion channel SLAH3, protein kinase CPK21 and its counterpart, protein phosphatase ABI1 were performed in Nicotiana benthamiana. Transient co-expression of CPK21 and the anion channel SLAH3, a highly mesophyll- specific homologue of the guard cell anion channel SLAC1, resulted in a combined, sterol-dependent localization of both proteins in DRMs. Supplementary co-expression of the counterpart protein phosphatase ABI1 induced dislocation of SLAH3 from DRMs, probably by inactivation of the protein kinase CPK21. CPK21 is known to regulate the anion channel SLAH3 by phosphorylation. ABI1 dephosphorylates CPK21 thus leading to deactivation and dislocation of SLAH3 from DRMs. All this regulative events are taking place in DRMs of A.th. mesophyll cells. This study presents the first evidence for a lipid raft-resident protein complex combining signaling and transport functions in A.th. Future perspectives for lipid raft research might target investigations on the lipid raft localization of candidate DRM proteins under presence of abiotic and biotic stress factors. For instance, which alterations in the DRM protein composition are detectable upon exogenous application of the plant hormone ABA? Quantitative proteomics approaches will surely increase our knowledge of the post-transcriptional regulation of gene activity under drought stress conditions.
Inoculation with plant pathogens induces a diverse range of plant responses which potentially contribute to disease resistance or susceptibility. Plant responses occuring in consequence of pathogen infection include activation of classical defence pathways and changes in metabolic activity. The main defence route against hemibiotrophic bacterial pathogens such as Pseudomonas syringae is based on the phytohormone salicylic acid (SA). SA-mediated responses are strictly regulated and have also been shown to depend on external factors, e.g. the presence of light. A major goal of this work was to provide a better understanding of the light dependency of plant defence responses mediated through SA. The second part of the project focussed on the influence of plant sterols on plant resistance. I analyzed leaf lipid composition and found that accumulation of the phytosterol stigmasterol in leaves and in isolated (plasma) membranes is a significant plant metabolic process occurring upon pathogen infection.
Regulation of pathogen-inducible volatile compounds in Arabidopsis and their role in plant defense
(2010)
Plants are constantly attacked by pathogenic microbes. As a result, they have evolved a plethora of constitutive and inducible defense responses to defend against attempted pathogen infection. Although volatile organic compounds have been implicated in plant defense, direct evidence of their function in plant resistance is still lacking. I have examined the role of VOCs in Arabidopsis defense against the hemibiotrophic bacterial pathogen Pseudomonas syringae pv. maculicola. The obtained results show that the vegetative parts of Arabidopsis produces and emits the volatile phenylpropanoid MeSA and three kinds of terpenoids, (E,E)-4,8,12-trimethyltrideca-1,3,7,11-tetraene (TMTT), alpha-ionon and beta-farnesen, upon avirulent and virulent P. syringae inoculation. Whereas the most abundant volatiles, MeSA and TMTT, are already produced at early stages of infection in the compatible and incompatible interaction, enhanced emission of alpha-ionon and beta-farnesen can only be detected in later stages of the compatible interaction. It was revealed that pathogen-induced synthesis of TMTT in Arabidopsis requires the JA signaling pathway but occurs independently of SA defense signaling. Similarly, the production of MeSA is dependent on JA signaling but not on the SA defense signaling pathway. Furthermore, production of MeSA is dependent on the function of ISOCHORISMATE SYNTHASE1, which produces its precursor SA. Upon inoculation with avirulent P. syringae, endogenously produced JA activates the JA signalling pathway to mediate MeSA and TMTT synthesis. By contrast, in the compatible Arabidopsis-Psm interaction, production of MeSA predominantly depends on the P. syringea the virulence factor coronatine, which activates JA downstream signaling. To learn more about the role of inducible VOCs in plant defense responses, I have identified an Arabidopsis T-DNA insertions line with a defect in the TERPENE SYNTHASE4 (TPS4) gene. Emission profiles from this mutant revealed that the induced production of TMTT but not of alpha-ionone, beta-farnesene or MeSA are abolished, demonstrating that TPS4 specifically regulates the P. syringae-induced synthesis of TMTT in Arabidopsis. The lack of TMTT in tps4 mutants, however, does not affect plant defense responses and resistance induction against P. syringae. This excludes a role of the terpenoid as an effective phytoalexin in Arabidopsis leaves against the bacterial pathogen. Moreover, tps4 mutant plants are still able to mount a SAR response, excluding a signaling function of TMTT during SAR. An important aim of our studies was to address the defensive role of MeSA, the major VOC emitted from P. syringae-inoculated Arabidopsis leaves. MeSA has been recently proposed as a critical long distance signal in the development of SAR. I found that two independent T-DNA insertions lines with defects in expression of the pathogen-inducible SA methyl transferase gene BSMT1 are completely devoid of pathogen-induced production of MeSA. However, bsmt1 mutant plants are capable to increase the level of SA in systemic, non-infected leaves of Arabodopsis and develop SAR like wild-type plants upon local P. syringae-inoculation. Thus, MeSA does not function as a critical SAR signal in Arabidopsis. Further experiments showed that SA accumulation in distant leaves occurs due to de novo synthesis through isochorismate synthase. In addition, we also ruled out a critical defensive role of MeSA at inoculation sites, because bsmt1 mutants are able to build up SA-dependent defense responses and local resistance in a wild-type-like manner. The conversion of SA to MeSA and subsequently emission of MeSA from the plant might help the plant to detoxify an excess of SA. This process is regulated by the JA pathway and might be one means to mediate negative crosstalk between JA and SA signaling. Moreover, the COR-triggered conversion of SA to MeSA and emission of the volatile methyl ester could be a way by which virulent P. syringae is able to attenuate the SA-defense pathway.
NO has been described as an important component involved in the development of the hypersensitive reaction (Delledonne et.al., 1998). Furthermore, NO induces expression of a set of defence gene, such as PR-1, PAL1 and chalcone synthase (CHS), and accumulation of SA (Durner et al., 1998). In this study, transgenic plants with altered NO levels were used to study the role of NO in plant defence. Arabidopsis plants which, due to expression of a bacterial NO dioxygenase, exhibit lower levels of NO than wild-type plants, show several weakened defence response, including the oxidative burst and expression of phenylpropanoid pathway genes. By contrast, constitutive expression of a bacterial NO synthase in Arabisopsis results in increased levels of endogenous NO. However, these plants do not show constitutively activated defence responses, but suffer from increased susceptibility to various strains of P. syringae. This might indicate that a gradient in NO production rather than constitutive elevation of NO is necessary to trigger plant defence responses. Nevertheless, NO seems to be important for regulation of the oxidative state in plant cells. This function of NO is important during leaf senescence. The data of the present work indicate that NO acts as senescence-delaying factor during plant development. The molecular action of NO in plants and signalling cascades in which NO is involved as second messenger are still poorly understood. Experiments addressing the selective quantification of NO in intact plant tissue, the identification of NO-target proteins as well as the function of NO-modified biomolecules might help to understand the role of NO in plants. Non-host resistance consists of several layers of defence that include preformed compounds existing in plants before pathogen infection and induced defences which the plant activates after recognition of a pathogen. The role of inducible defences in preventing multiplication of non-adapted bacteria is not clear. Our experiments suggest that to restrict non-adapted bacterial growth, pre-formed antimicrobial compounds and an early inducible cell wall-based defence might play an important role in Arabidopsis leaves. Upon inoculation with non-adapted bacteria, we have observed early, TTSS-independent up-regulation of PAL1 and BCB, two lignin biosynthesis genes which might be involved in papilla formation or other kinds of cell wall fortification. Moreover, Arabidopsis pal1 knockout lines permit significantly higher survival of non-adapted bacteria in leaves than wild-type plants, suggesting a functional importance of PAL1 up-regulation. Although non-host bacteria, like host bacteria, induce accumulation of SA and PR gene expression in a TTSS-dependent manner, SA-dependent or JA/ET-dependent defences do not directly contribute to non-host resistance. Moreover, non-adapted bacteria activate similar defence signalling pathways as do host bacteria. However, because of varieties in effector protein composition between different non-adapted bacterial strains, the activated signalling pathways might also include different compounds. The Arabidopsis ecotype Ler 0 is more susceptible to a non-adapted strain of P. syringae than ecotype Col-0. Although differences in glucosinolate content and composition between those ecotypes exist, they are probably not a major reason for the observed difference in non-host resistance. To further understand the mechanisms underlying non-host resistance, the generation of double or triple mutants with deficits in both cell wall-based defences and SA-dependent signal cascades is necessary. Moreover, the study of genome polymorphism and composition of secondary metabolites between Ler-0 and Col-0 can shed new light into the mechanisms of non-host resistance against bacterial pathogens. Additionally, experiments addressing papilla formation and callose biosynthesis in Ler-0 and Col-0 could help to further elucidate bacterial non-host resistance. Our data indicate that localized contact of Arabidopsis leaves with non-adapted bacteria, type III secretion-defective P. syringae strains and bacterial pathogen-associated molecular patterns (PAMPs) induce systemic acquired resistance (SAR) at the whole plant level. This finding contrasts the general belief that an HR or other leaf necroses are required for SAR induction. The observed symptomless systemic response was abolished in all SAR-deficient mutants tested in this study, but was intact in the jar1 mutant, which is compromised in induction of ISR, indicating that non-host bacteria and PAMPs induce SAR in a mechanistically similar way than host bacteria. In addition, our data show that the extent of SA accumulation or PR gene expression induced at sites of virulent or avirulent P. syringae inoculation rather than the amount of tissue necroses or jasmonate accumulation determine the magnitude of SAR. The fact that systemic responses were also triggered after local treatment with type III secretion-defective P. syringae strains and bacterial PAMPs indicate that induction of SAR is TTSS-independent. Instead, recognition of general elicitors like flagellin and LPS play an important role in activation of the SAR process. To broaden the concept of PAMP-based SAR initiation, further general elicitors from bacteria and fungal pathogens should be tested for their capability to induce SAR. Screens for mutants with deficiency in SAR activation by individual PAMPs can help to identify new components involved in the SAR signalling cascade. Possible functions of PAMPs as mobile systemic signals should be tested in future experiments. By selection of candidate genes whose expression is up-regulated in Arabidopsis leaves infected with avirulent and virulent P. syringae and pathophysiological analyses of corresponding T-DNA knockout lines, FLAVIN-DEPENDENT MONOOXYGENASE1 (FMO1) was identified as a key SAR regulator. SAR triggered by P. syringae is completely abolished in fmo1 mutant plants, and pathogen-induced expression of FMO1 in systemic leaves is closely correlated with the capability of different Arabidopsis lines to develop SAR. According to our findings, we have proposed that the FMO1 acts in signal amplification in non-inoculated, systemic leaves to trigger SAR. Experimental verification of the postulated potential amplification cycle underlying SAR should be tested in future experiments. The generation of transgenic lines expressing FMO1::GFP will provide useful information about the cellular localization of the FMO1 protein. Moreover, a comparative metabolomic analysis using SAR-induced wild-type, fmo1 knockout and FMO1 overexpressing lines can be used to identify substrates and reaction products of the FMO1 monooxygenase. As the single yeast FMO (yFMO) provides oxidizing equivalents at the ER for correct protein folding, expression of FMO1 in yfmo mutant yeast combined with protein activity assays might indicate whether FMO1 exhibits functional similarities with yeast FMO, e.g. in assuring proper folding of ER-targeted proteins essential for SAR establishment. Identification of further genes involved in activation of systemic resistance and biochemical characterization of the corresponding proteins can help to understand the SAR process in more detail.