@article{HackenbergHakanpaeaeCaietal.2018,
  author    = {Hackenberg, Claudia and Hakanpaeae, Johanna and Cai, Fei and Antonyuk, Svetlana and Eigner, Caroline and Meissner, Sven and Laitaoja, Mikko and Janis, Janne and Kerfeld, Cheryl A. and Dittmann, Elke and Lamzin, Victor S.},
  title     = {Structural and functional insights into the unique CBS-CP12 fusion protein family in cyanobacteria},
  series = {Proceedings of the National Academy of Sciences of the United States of America},
  volume    = {115},
  journal   = {Proceedings of the National Academy of Sciences of the United States of America},
  number    = {27},
  publisher = {National Acad. of Sciences},
  address   = {Washington},
  issn      = {0027-8424},
  doi       = {10.1073/pnas.1806668115},
  pages     = {7141 -- 7146},
  year      = {2018},
  abstract  = {Cyanobacteria are important photosynthetic organisms inhabiting a range of dynamic environments. This phylum is distinctive among photosynthetic organisms in containing genes encoding uncharacterized cystathionine beta-synthase (CBS)-chloroplast protein (CP12) fusion proteins. These consist of two domains, each recognized as stand-alone photosynthetic regulators with different functions described in cyanobacteria (CP12) and plants (CP12 and CBSX). Here we show that CBS-CP12 fusion proteins are encoded in distinct gene neighborhoods, several unrelated to photosynthesis. Most frequently, CBS-CP12 genes are in a gene cluster with thioredoxin A (TrxA), which is prevalent in bloom-forming, marine symbiotic, and benthic mat cyanobacteria. Focusing on a CBS-CP12 from Microcystis aeruginosa PCC 7806 encoded in a gene cluster with TrxA, we reveal that the domain fusion led to the formation of a hexameric protein. We show that the CP12 domain is essential for hexamerization and contains an ordered, previously structurally uncharacterized N-terminal region. We provide evidence that CBS-CP12, while combining properties of both regulatory domains, behaves different from CP12 and plant CBSX. It does not form a ternary complex with phosphoribulokinase (PRK) and glyceraldehyde-3-phosphate dehydrogenase. Instead, CBS-CP12 decreases the activity of PRK in an AMP-dependent manner. We propose that the novel domain architecture and oligomeric state of CBS-CP12 expand its regulatory function beyond those of CP12 in cyanobacteria.},
  language  = {en}
}
@phdthesis{Siemiatkowska2020,
  author    = {Siemiatkowska, Beata},
  title     = {Redox signalling in plants},
  doi       = {10.25932/publishup-48911},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-489119},
  school      = {Universit{\"a}t Potsdam},
  pages     = {127},
  year      = {2020},
  abstract  = {Once proteins are synthesized, they can additionally be modified by post-translational modifications (PTMs). Proteins containing reactive cysteine thiols, stabilized in their deprotonated form due to their local environment as thiolates (RS-), serve as redox sensors by undergoing a multitude of oxidative PTMs (Ox-PTMs). Ox-PTMs such as S-nitrosylation or formation of inter- or intra-disulfide bridges induce functional changes in these proteins. Proteins containing cysteines, whose thiol oxidation state regulates their functions, belong to the so-called redoxome. Such Ox-PTMs are controlled by site-specific cellular events that play a crucial role in protein regulation, affecting enzyme catalytic sites, ligand binding affinity, protein-protein interactions or protein stability. Reversible protein thiol oxidation is an essential regulatory mechanism of photosynthesis, metabolism, and gene expression in all photosynthetic organisms. Therefore, studying PTMs will remain crucial for understanding plant adaptation to external stimuli like fluctuating light conditions. Optimizing methods suitable for studying plants Ox-PTMs is of high importance for elucidation of the redoxome in plants. This study focusses on thiol modifications occurring in plant and provides novel insight into in vivo redoxome of Arabidopsis thaliana in response to light vs. dark. This was achieved by utilizing a resin-assisted thiol enrichment approach. Furthermore, confirmation of candidates on the single protein level was carried out by a differential labelling approach. The thiols and disulfides were differentially labelled, and the protein levels were detected using immunoblot analysis. Further analysis was focused on light-reduced proteins. By the enrichment approach many well studied redox-regulated proteins were identified. Amongst those were fructose 1,6-bisphosphatase (FBPase) and sedoheptulose-1,7-bisphosphatase (SBPase) which have previously been described as thioredoxin system targeted enzymes. The redox regulated proteins identified in the current study were compared to several published, independent results showing redox regulated proteins in Arabidopsis leaves, root, mitochondria and specifically S-nitrosylated proteins. These proteins were excluded as potential new candidates but remain as a proof-of-concept to the enrichment experiments to be effective. Additionally, CSP41A and CSP41B proteins, which emerged from this study as potential targets of redox-regulation, were analyzed by Ribo-Seq. The active translatome study of csp41a mutant vs. wild-type showed most of the significant changes at end of the night, similarly as csp41b. Yet, in both mutants only several chloroplast-encoded genes were altered. Further studies of CSP41A and CSP41B proteins are needed to reveal their functions and elucidate the role of redox regulation of these proteins.},
  language  = {en}
}
@phdthesis{Mueller2013,
  author    = {M{\"u}ller, Mike-Freya},
  title     = {Die Glutathionperoxidase 2 : physiologische Funktion und Rolle in der Azoxymethan-induzierten Colonkanzerogenese},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-66955},
  school      = {Universit{\"a}t Potsdam},
  year      = {2013},
  abstract  = {Das Selenoprotein Glutathionperoxidase 2 (GPx2) ist ein epithelzellspezifisches, Hydroperoxide-reduzierendes Enzym, welches im Darmepithel, vor allem in den proliferierenden Zellen des Kryptengrundes, exprimiert wird. Die Aufrechterhaltung der GPx2-Expression im Kryptengrund auch bei subad{\"a}quatem Selenstatus k{\"o}nnte darauf hinweisen, dass sie hier besonders wichtige Funktionen wahrnimmt. Tats{\"a}chlich weisen GPx2 knockout (KO)-M{\"a}use eine erh{\"o}hte Apoptoserate im Kryptengrund auf. Ein Ziel dieser Arbeit war es deshalb, die physiologische Funktion der GPx2 n{\"a}her zu untersuchen. In Kryptengrundepithelzellen aus dem Colon selenarmer GPx2 KO-M{\"a}use wurde eine erh{\"o}hte Caspase 3/7-Aktivit{\"a}t im Vergleich zum Wildtyp (WT) festgestellt. Zudem wiesen diese Zellen eine erh{\"o}hte Suszeptibilit{\"a}t f{\"u}r oxidativen Stress auf. Die GPx2 gew{\"a}hrleistet also den Schutz der proliferierenden Zellen des Kryptengrundes auch bei subad{\"a}quater Selenversorgung. Des Weiteren wurde im Colon selenarmer (-Se) und -ad{\"a}quater (+Se) GPx2 KO-M{\"a}use im Vergleich zum WT eine erh{\"o}hte Tumornekrosefaktor α-Expression und eine erh{\"o}hte Infiltration von Makrophagen festgestellt. Durch F{\"u}tterung einer selensupplementierten Di{\"a}t (++Se) konnte dies verhindert werden. In GPx2 KO-M{\"a}usen liegt demnach bereits basal eine niedriggradige Entz{\"u}ndung vor. Dies unterstreicht, dass GPx2 vor allem eine wichtige antiinflammatorische Funktion im Darmepithel besitzt. Dem Mikron{\"a}hrstoff Selen werden protektive Funktionen in der Colonkanzerogenese zugeschrieben. In einem Mausmodell der Colitis-assoziierten Colonkanzerogenese wirkte GPx2 antiinflammatorisch und hemmte so die Tumorentstehung. Auf der anderen Seite wurden jedoch auch prokanzerogene Eigenschaften der GPx2 aufgedeckt. Deshalb sollte in dieser Arbeit untersucht werden, welchen Effekt ein GPx2 knockout in einem Modell der sporadischen, durch Azoxymethan (AOM) induzierten, Colonkanzerogenese hat. Im WT kam es in pr{\"a}neoplastischen L{\"a}sionen h{\"a}ufig zu einer erh{\"o}hten GPx2-Expression im Vergleich zur normalen Darmmucosa. Eine derartige Steigerung der GPx2-Expression wurde auch in der humanen Colonkanzerogenese beschrieben. Das Fehlen der GPx2 resultierte in einer verminderten Entstehung von Tumoren (-Se und ++Se) und pr{\"a}neoplastischen L{\"a}sionen (-Se und +Se). Somit f{\"o}rderte GPx2 die Tumorentstehung im AOM-Modell. Acht Stunden nach AOM-Gabe war im GPx2 KO-Colon im Vergleich zum WT eine erh{\"o}hte Apoptoserate in der Kryptenmitte (-Se, +Se), nicht jedoch im Kryptengrund oder in der ++Se-Gruppe zu beobachten. M{\"o}glicherweise wirkte GPx2 prokanzerogen, indem sie die effiziente Elimination gesch{\"a}digter Zellen in der Tumorinitiationsphase verhinderte. Eine {\"a}hnliche Wirkung w{\"a}re auch durch die erh{\"o}hte GPx2-Expression in der Promotionsphase denkbar. So k{\"o}nnte GPx2 proliferierende pr{\"a}neoplastische Zellen vor oxidativem Stress, Apoptosen, oder auch der Antitumorimmunit{\"a}t sch{\"u}tzen. Dies k{\"o}nnte durch ein Zusammenwirken mit anderen Selenoproteinen wie GPx1 und Thioredoxinreduktasen, f{\"u}r die ebenfalls auch prokanzerogene Funktionen beschrieben wurden, verst{\"a}rkt werden. Eine wichtige Rolle k{\"o}nnte hier die Modulation des Redoxstatus in Tumorzellen spielen. Die Variation des Selengehalts der Di{\"a}t hatte im WT einen eher U-f{\"o}rmigen Effekt. So traten in der -Se und ++Se-Gruppe tendenziell mehr und gr{\"o}ßere Tumore auf, als in der +Se Gruppe. Zusammenfassend sch{\"u}tzt GPx2 also die proliferierenden Zellen des Kryptengrundes. Sie k{\"o}nnte jedoch auch proliferierende transformierte Zellen sch{\"u}tzen und so die sporadische, AOM-induzierte Colonkanzerogenese f{\"o}rdern. In einem Modell der Colitis-assoziierten Colonkanzerogenese hatte GPx2 auf Grund ihrer antiinflammatorischen Wirkung einen gegenteiligen Effekt und hemmte die Tumorentstehung. Die Rolle der GPx2 in der Colonkanzerogenese ist also abh{\"a}ngig vom zugrunde liegenden Mechanismus und wird maßgeblich von der Beteiligung einer Entz{\"u}ndung bestimmt.},
  language  = {de}
}
@phdthesis{Kolbe2005,
  author    = {Kolbe, Anna},
  title     = {Redox-regulation of starch and lipid synthesis in leaves},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-6388},
  school      = {Universit{\"a}t Potsdam},
  year      = {2005},
  abstract  = {Post-translational redox-regulation is a well-known mechanism to regulate enzymes of the Calvin cycle, oxidative pentose phosphate cycle, NADPH export and ATP synthesis in response to light. The aim of the present thesis was to investigate whether a similar mechanism is also regulating carbon storage in leaves. Previous studies have shown that the key-regulatory enzyme of starch synthesis, ADPglucose pyrophosphorylase (AGPase) is inactivated by formation of an intermolecular disulfide bridge between the two catalytic subunits (AGPB) of the heterotetrameric holoenzyme in potato tubers, but the relevance of this mechanism to regulate starch synthesis in leaves was not investigated. The work presented in this thesis shows that AGPase is subject to post-translational redox-regulation in leaves of pea, potato and Arabidopsis in response to day night changes. Light was shown to trigger posttranslational redox-regulation of AGPase. AGPB was rapidly converted from a dimer to a monomer when isolated pea chloroplasts were illuminated and from a monomer to a dimer when preilluminated leaves were darkened. Conversion of AGPB from dimer to monomer was accompanied by an increase in activity due to changes in the kinetik properties of the enzyme. Studies with pea chloroplast extracts showed that AGPase redox-activation is mediated by thioredoxins f and m from spinach in-vitro. In a further set of experiments it was shown that sugars provide a second input leading to AGPase redox activation and increased starch synthesis and that they can act as a signal which is independent from light. External feeding of sugars such as sucrose or trehalose to Arabidopsis leaves in the dark led to conversion of AGPB from dimer to monomer and to an increase in the rate of starch synthesis, while there were no significant changes in the level of 3PGA, an allosteric activator of the enyzme, and in the NADPH/NADP+ ratio. Experiments with transgenic Arabidopsis plants with altered levels of trehalose 6-phosphate (T6P), the precursor of trehalose synthesis, provided genetic evidence that T6P rather than trehalose is leading to AGPase redox-activation. Compared to Wt, leaves expressing E.coli trehalose-phosphate synthase (TPS) in the cytosol showed increased activation of AGPase and higher starch level during the day, while trehalose-phosphate phosphatase (TPP) overexpressing leaves showed the opposite. These changes occurred independently of changes in sugar and sugar-phosphate levels and NADPH/NADP+ ratio. External supply of sucrose to Wt and TPS-overexpressing leaves led to monomerisation of AGPB, while this response was attenuated in TPP expressing leaves, indicating that T6P is involved in the sucrose-dependent redox-activation of AGPase. To provide biochemical evidence that T6P promotes redox-activation of AGPase independently of cytosolic elements, T6P was fed to intact isolated chloroplasts for 15 min. incubation with concentrations down to 100 µM of T6P, but not with sucrose 6-phosphate, sucrose, trehalose or Pi as controls, significantly and specifically increased AGPB monomerisation and AGPase activity within 15 minutes, implying T6P as a signal reporting the cytosolic sugar status to the chloroplast. The response to T6P did not involve changes in the NADPH/NADP+ ratio consistent with T6P modulating redox-transfer to AGPase independently of changes in plastidial redox-state. Acetyl-CoA carboxylase (ACCase) is known as key-regulatory enzyme of fatty acid and lipid synthesis in plants. At the start of the present thesis there was mainly in vitro evidence in the literature showing redox-regulation of ACCase by DTT, and thioredoxins f and m. In the present thesis the in-vivo relevance of this mechanism to regulate lipid synthesis in leaves was investigated. ACCase activity measurement in leaf tissue collected at the end of the day and night in Arabidopsis leaves revealed a 3-fold higher activation state of the enzyme in the light than in the dark. Redox-activation was accompanied by change in kinetic properties of ACCase, leading to an increase affinity to its substrate acetyl-CoA . In further experiments, DTT as well as sucrose were fed to leaves, and both treatments led to a stimulation in the rate of lipid synthesis accompanied by redox-activation of ACCase and decrease in acetyl-CoA content. In a final approach, comparison of metabolic and transcript profiling after DTT feeding and after sucrose feeding to leaves provided evidence that redox-modification is an important regulatory mechanism in central metabolic pathways such as TCA cycle and amino acid synthesis, which acts independently of transcript levels.},
  subject      = {Redoxreaktion},
  language  = {en}
}