JAK/STAT SIGNALING REGULATES GAMETOGENESIS AND AGE-RELATED REPRODUCTIVE MAINTENANCE

Giedt, Michelle Suzanne

01 January 2018

Cell signaling is central to integration of internal and external cues that regulate development and homeostasis. Most development is thought of as pre-adult, but limited developmental processes occur in adults. Gametogenesis incorporates elements of both these facets, with a distinct developmental plan for gamete synthesis which is regulated by integration of homeostatic inputs such as nutrient status, and environmental cues. Signaling pathways integrate and transduce information from these cues to evoke a response. A decline in homeostasis and subsequent cues occurs over time, in the case of reproductive tissues leading to a progressive loss of fertility. The Janus Kinase and Signal Transducer and Activator of Transcription or Jak/Stat signaling pathway is conserved between vertebrates and invertebrates and is necessary for numerous functions needed to maintain organism and reproductive homeostasis, as well as contributing to various developmental events. The pathway in the fruit fly Drosophila melanogaster, is composed of a single receptor, Domeless, one Janus kinase, Hopscotch, one known effector, Stat92E, and the Unpaired family of ligands consisting of Upd, Upd2, and Upd3. Jak/Stat signaling is highly pleiotropic in both sexes with involvement in homeostasis and reproduction, making it an ideal model for studying the role of signaling in reproductive aging. Reduction of pathway activity in females results in a higher proportion of unfertilized eggs, which increases with age, and in males leads to a premature onset of infertility. Central to both is integration through cell signaling to evoke an appropriate response. This dissertation explores two of the requirements for Jak/Stat signaling: the pleiotropic requirement for Jak/Stat activity during oogenesis and male reproductive maintenance. Jak/Stat functions from the beginning of oogenesis, in the stem cell niche. From there it participates in multiple functions including specification of a subset of somatic cells called the border cells through the polar cells, a pair of cells at either pole of the egg. Pathway stimulation in the border cells drives their migration with the polar cells to the oocyte boundary, where the polar cells each form an extension in a coordinated manner into the micropyle, the means for sperm entrance during fertilization. Loss of Jak/Stat activity in the border cells prevents border cell migration. While border cell migration has been well studied, polar cell involvement after completion of border cell migration is less well known. To investigate the requirements for polar cell activity and Jak/Stat activity after the completion of border cell migration, we reduced Jak/Stat signaling in the polar cells which, while having no effect on border cell migration, results in blocked micropyles due to loss of coordination of extensions during their outgrowth. Reduced function in the polar cells did not significantly affect expression of adhesion molecules. But, the loss of Stat92E is phenocopied by loss of DE-cadherin. Hence, these results indicate a previously unknown autocrine requirement for Jak/Stat activity in the polar cells. The testes also have a continuous requirement for Jak/Stat activity for stem cell maintenance and differentiation of the germline into mature sperm. Reproductive maintenance not only requires sustained production of gametes, but reproductive tissues are also subject to deterioration of homeostatic functions that contribute to organismal aging. Males from thirty-nine lines of the Drosophila Genetic Reference Panel (DGRP), a panel of inbred, fully sequenced lines, were screened for age at infertility. Data were used to perform a genome-wide association study (GWAS) to identify the genetic architecture of reproductive aging. Candidate variants associated with cell signaling regulators, genes with functions in maintaining cell homeostasis, and organism behavior were uncovered. Notably, several SNPs fell in and near Ptp61F, a negative regulator of Jak/Stat activity. While variants in the primary components of the Jak/Stat pathway were not identified, the general classes of candidate loci functions reflect the requirements for homeostasis, metabolism, and development that have been shown by other studies examining the genetics of aging and fecundity. Thus, we show that Jak/Stat has an amazing amount of pleiotropy that encompasses both the real-time functions of fertility and the time related process of aging.

Jak/Stat pathway

Drosophila

micropyle

polar cells

senescence

fertility

Cell Biology

Developmental Biology

Genetics

INVESTIGATING SMOKE EXPOSURE AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) WITH A CALIBRATED AGENT BASED MODEL (ABM) OF IN VITRO FIBROBLAST WOUND HEALING.

Ratti, James A

01 January 2018

COPD is characterized by tissue inflammation and impaired remodeling that suggests fibroblast maintenance of structural homeostasis is dysregulated. Thus, we performed in vitro wound healing experiments on normal and diseased human lung fibroblasts and developed an ABM of fibroblasts closing a scratched monolayer using NetLogo to evaluate differences due to COPD or cigarette smoke condensate exposure. This ABM consists of a rule-set governing the healing response, accounting for cell migration, proliferation, death, activation and senescence rates; along with the effects of heterogeneous activation, phenotypic changes, serum deprivation and exposure to cigarette smoke condensate or bFGF. Simulations were performed to calibrate parameter-sets for each cell type using in vitro data of scratch-induced migration, viability, senescence-associated beta-galactosidase and alpha-smooth muscle actin expression. Parameter sensitivities around each calibrated parameter-set were analyzed. This model represents the prototype of a tool designed to explore fibroblast functions in the pathogenesis of COPD and evaluate potential therapies.

cellular automata

contact inhibition

senescence

myofibroblast

oxidative stress

hypoxia

Computational Engineering

Disease Modeling

Systems Biology

Proteomic approaches to profiling of cysteine proteases expressed in leaves and root nodules during natural senescence of the soybean plant

Karumazondo, Rumbidzai Patience

January 2011

Thesis (M.Sc. (Biochemistry)) -- University of Limpopo, 2011 / Soybean is one of the most cultivated legume plants in developing countries. Nodule senescence is a major limitation in producing high yields of soybean as it coincides with the pod filling stage. Delaying nodule senescence could be a way of increasing the yield of soybean therefore determination of the role of cysteine protease in soybean is of vital importance. In this study, soybean plants were grown under controlled temperature and light conditions. Leaves and root crown nodules were collected at 4, 6, 10, 12 and 16 weeks of age. In a comparative 1-dimensional SDS-PAGE analysis of soybean nodule proteomes as the plant matured, it showed differences in proteins expressed as shown by different banding patterns with less variation between the younger soybean nodule extracts (4, 6 and 10 weeks old) as compared to the older ones (12 and 16 weeks old). As determined by azocasein assay and protease zymography, the protease activity of the nodule extracts generally decreased with an increase in the age of the nodules whereas that of the leaves increased as the plants grew older. Cysteine proteases in the soybean nodule extracts readily cleaved the Z-Arg-Arg-AMC substrate with the highest activity shown in the younger nodules as compared to the older ones. In the leaf extracts, cysteine protease activity increased with age of the leaves. DCG-04, a biotinylated irreversible inhibitor, proved to be an effective label in profiling of activity of cysteine proteases in 1-dimensional and 2-dimensional systems. The labelling was inhibited specifically by cysteine protease inhibitor, E-64. In root nodules, the DCG-04 probing demonstrated that the expression of cysteine proteases is higher in early stages of development of the soybean nodules as compared to the later stages whereas in the leaves, there is higher expression of cysteine proteases in the old leaves (16 weeks). Using 2-dimensional polyacrylamide gel electrophoresis, five cysteine protease isoforms were visualised with the size ranging from approximately 25 to 30 kDa and a pI range of 4-6. In older nodules (12 and 16 weeks old) the higher pI isoforms are down-regulated with the 26 kDa and pI 4.5 protease being the predominant isoform. Affinity precipitation of the cysteine proteases yielded a strong band with the size of about 26 kDa. All assays used show that while in leaves, the expected trend of high expression of cysteine proteases in senescing leaves is observed, in soybean nodules the expression of cysteine proteases decreases with senescence. There is, therefore, no correlation between senescence and cysteine proteases in nodules. The highly expressed cysteine protease in young nodules could play a developmental or regulatory role during the early stages of development.

Soybean plant

Natural senescence

Proteins

Soybean

Plant proteins

Cysteine Proteinases

Neutral proteinases

Nitrogen Cycling in the Rhizosphere of Cheatgrass and Crested Wheatgrass: Contributions of Root Exudates and Senescence

Morris, Kendalynn A.

01 May 2014

Cheatgrass is an invasive weed that has come to dominate large areas of the western United States. Once an ecosystem has been converted to a cheatgrass monoculture, it is extremely difficult to restore native vegetation. Cheatgrass negatively impacts wildlife and increases wildfire frequency and intensity. Understanding how cheatgrass so effectively invades western ecosystems is essential to turning the tide of invasion. One possible key to cheatgrass’ success is alteration of soil nutrient cycling. The goal of this study is to explore how nitrogen (N) may accumulate in cheatgrass soils via redistribution of N within soil N pools. To accomplish this we investigated soil N cycling in soils underneath cheatgrass and crested wheatgrass. We used a 15N isotope tracer to determine the contribution of root exudates to soil N pools. During the 1-week 15N tracer experiment, cheatgrass roots exuded more than twice as much N (0.11 mg N kg-1 soil d-1) as crested wheatgrass roots (0.05 mg N kg-1 soil d-1). We propose that exudation of high N content root exudates leads to the changes in soil N pool size and transformation rates commonly observed in soils under cheatgrass. This research uses a simple and relatively inexpensive isotope tracer to shed light on mechanisms by which invasive plants may alter soil processes. By understanding these mechanisms we may be able to develop strategies for better managing cheatgrass invasion.

Nitrogen Cycling

Rhizosphere of Cheatgrass

Crested Wheatgrass

Root Exudates

Senescence

Ecology and Evolutionary Biology

The Role of Proteases in Plant Development

Garcia-Lorenzo, Maribel

January 2007

Proteases play key roles in plants, maintaining strict protein quality control and degrading specific sets of proteins in response to diverse environmental and developmental stimuli. Similarities and differences between the proteases expressed in different species may give valuable insights into their physiological roles and evolution. Systematic comparative analysis of the available sequenced genomes of two model organisms led to the identification of an increasing number of protease genes, giving insights about protein sequences that are conserved in the different species, and thus are likely to have common functions in them and the acquisition of new genes, elucidate issues concerning non-functionalization, neofunctionalization and subfunctionalization. The involvement of proteases in senescence and PCD was investigated. While PCD in woody tissues shows the importance of vacuole proteases in the process, the senescence in leaves demonstrate to be a slower and more ordered mechanism starting in the chloroplast where the proteases there localized become important. The light-harvesting complex of Photosystem II is very susceptible to protease attack during leaf senescence. We were able to show that a metallo-protease belonging to the FtsH family is involved on the process in vitro. Arabidopsis knockout mutants confirmed the function of FtsH6 in vivo.

Comparative genomics

protease

PCD

leaf senescence

FtsH

Arabidopsis

Populus

Biochemistry

Biokemi

The immortalization process of T cells : with focus on the regulation of telomere length and telomerase activity

Degerman, Sofie

January 2010

Cellular immortalization is a major hallmark of cancer and is a multi-step process that requires numerous cell-type specific changes, including inactivation of control mechanisms and stabilization of telomere length. The telomeres at the chromosome ends are essential for genomic stability, and limit the growth potential of most cells. With each cell division, telomeres are shortened. Short telomeres may induce an irreversible growth arrest stage called senescence, or a growth crisis stage characterized by high genomic instability and cell death. Only very rarely do cells escape from crisis and become immortal, a stage that has been associated with the activation of the telomerase enzyme which can elongate and stabilize the telomeres. The processes leading to senescence bypass, growth crisis escape and finally immortalization are only beginning to be elucidated. Most of our knowledge of the immortalization process is based on analyses of human fibroblast and epithelial cell cultures immortalized by genetic modification. In this thesis, spontaneously immortalized human T lymphocytes derived from patients with Nijmegen Breakage Syndrome and a healthy individual were used to identify critical events for senescence bypass and immortalization. Genetic analysis showed a clonal progression and non-random genetic changes including the amplification of chromosomal region 2p13-21 as an early event in the immortalization process. Telomere length gradually shortened at increasing population doublings and growth crisis was associated with critically short telomeres. The clone(s) that escaped growth crisis demonstrated a logarithmic growth curve, very short telomeres and, notably, no increase in telomerase activity or expression of the telomerase catalytic gene, hTERT. Instead, upregulation of telomerase activity and telomere length stabilization were late events in T lymphocyte immortalization. Escape from crisis was associated with downregulation of DNA damage response genes and altered expression of cell cycle regulators and genes controlling the cellular senescence program. These data indicated that a number of layers of regulation are important in the process of immortalization and to provide further mechanistic detail, epigenetic analysis was carried out. Genome wide methylation array analysis identified early and step-wise methylation changes during the immortalization process. Interestingly, applying these findings to tumors of T cell origin revealed commonly methylated CpG sites in transformed cells. Deregulated gene expression of the polycomb complexes may have contributed to the epigenetic changes observed. Taken together, our analysis of spontaneously immortalized T cell cultures identified several steps in the immortalization process including genetic, epigenetic, gene expression and telomere/telomerase regulatory events, contributing further insights to the complexity of cancer cell immortalization.

immortalization

senescence

T cells

Nijmegen breakage syndrome

telomere

telomerase

hTERT

generic aberrations

methylation

MEDICINE

MEDICIN

Will the Timing of Temperate Deciduous Trees' Budburst and Leaf Senescence Keep up with a Warming Climate?

Salk, Carl F.

January 2011

<p>Recent changes in the timing of annual events are a sign that climate change is already impacting ecosystems. Carbon sequestration by forests increases with longer growing seasons. Biodiversity can be affected by mis-timing of events through shading interactions and frost damage. Projecting forests' ability to provide these ecosystem services in the future requires an understanding of trees' phenological responses to a new climate. I begin by proposing a first order definition of an `optimal' phenological response to warming: that the mean temperature following budburst should remain essentially constant. Analogously, the temperature preceding senescence can serve the same role. </p><p>To understand which environmental cues will drive future changes in phenology, I assimilate clues from observational and experimental literature. For budburst in woody plants, spring warmth, over-winter chilling and light drive nearly all behavior, but species' responses vary widely. Species using chilling or light as safety mechanisms against budburst during mid-winter thaws are thought to be less able to phenologically track a warming climate. However, I show that even species cued solely by spring warmth are likely to under-track temperature changes. Fall cues are more idiosyncratic, and a plant's driver of senescence is likely to vary from year to year. </p><p>Models are a tempting method to untangle species budburst cues and forecast phenology under warmer climate scenarios. I tested two models' ability to recover parameters used to simulate budburst data. The simpler model was cued only by spring warmth while the complex one modulated warmth requirements with chilling exposure. For the simple model, parameters could be recovered consistently from some, but not all, regions of parameter space. The complex model's parameters were largely unrecoverable. To understand the consequences of parameter uncertainty, I applied both models to an 18 year phenological record of 13 deciduous tree species. While a few species fell into identifiable regions of the simple model's parameter space, most did not, and projected budburst dates had wide parameter-derived uncertainty intervals. These bands were wider still under a 5°C warming scenario. Even greater uncertainty resulted from the complex model.</p><p>To better understand plants' potential for growing season extension I subjected seedlings to warmer climates in a series of open-topped chambers in sites at each end of the eastern deciduous biome. Soil and air were heated to 3 or 5°C above ambient, or left unheated. For nearly all species, warming hastened budburst and germination and delayed senescence. However, these events failed to track temperature changes, happening at warmer temperatures in hotter chambers. Individual species showed a remarkable variability of all events' dates within treatments, and even within chambers. Because phenological traits are heritable, this offers a potential for evolutionary response to climate change.</p><p>This research has shown that while individual trees extend their growing seasons under warmer temperatures, they typically under-respond to the magnitude of warming, suggesting forests' capacity for increased carbon sequestration may reach a limit. However, within populations, trees vary substantially in their phenological responses, forming a possibility for evolutionarily adaptation to changing cues.</p> / Dissertation

Environmental Sciences

Biology

Plant Biology

Budburst

Climate Change

Growing Season Length

Leaf Senescence

Phenology

Temperate Trees

The Cellular and Molecular Properties of Flavinoids in Prostate Cancer Chemoprevention

Haddad, Ahmed Qais

31 July 2008

Flavonoids are a large class of dietary polyphenols that have emerged as candidate agents for chemoprevention in prostate cancer. Despite the large number of known flavonoids (over 9000), only a few have been studied in prostate cancer to date. The work presented in this thesis describes the identification of novel anti-proliferative flavonoids, their molecular effects on cell cycle and related proliferation and survival pathways, and their chemopreventive properties in a murine model of prostate carcinogenesis. We identified several novel flavonoids with potent anti-proliferative effects in human prostate cancer cells in vitro. Non-prostate cell lines were generally resistant to the effect of these flavonoids. Two of the most potent flavonoids identified, 2,2-dihydroxychalcone (DHC) and fisetin, induced S and G2 phase cell cycle arrest in LNCaP and PC3 prostate cancer cells. Gene expression studies employing oligonucleotide microarray demonstrated profound down-regulation in gene expression of 75 key cell cycle (predominantly G2 and M phase) genes by DHC and fisetin, and the enhanced expression of 50 stress-response genes with important roles in cell proliferation and survival. DHC and fisetin induced apoptosis, but not accelerated senescence, in prostate cancer cells. The chemopreventive effect of 4 flavonoids identified from the in vitro studies was examined in an autochthonous murine model of prostate cancer (TRAMP). Mice were administered diets supplemented with 1% DHC, 1% fisetin or a combination of flavonoids (0.25% DHC, 0.25% fisetin, 0.25% quercetin, 0.25% luteolin) for 32 weeks. We demonstrated a significant reduction in genitourinary weight, and a reduction in prostate cancer grade in mice administered 1% DHC and combination diets. Flavonoid supplementation was, however, associated with gastrointestinal toxicity in some mice. Liquid chromatography-mass spectrometry demonstrated the accumulation of high levels of flavonoid in the prostates of TRAMP mice. These findings lay the foundation for further studies of flavonoids in clinical chemoprevention trials.

Flavonoids

Prostate Cancer

Cell cycle

Apoptosis

Senescence

TRAMP

Microarray

Diet

0379

Regulation of Telomerase by DNA and Protein Interactions

Sealey, David Charles Fitzgerald

01 September 2010

In most eukaryotes, chromosomes ends are protected by telomeres which are formed by repetitive DNA, specialized binding proteins, and higher order structures. Telomeres become shorter following replication due to the positioning and degradation of terminal RNA primers, as well as resection by nucleases. Extensive telomere shortening over many cell cycles elicits a DNA damage checkpoint that culminates in senescence or, in the absence of tumor suppressor pathways, apoptosis. These effects block the expansion of cells with unstable genomes, but can also precipitate disease in tissues that rely on regeneration for function. In many unicellular eukaryotes and proliferative human cells including cancer cells, telomeres can be maintained by the telomerase reverse transcriptase (TERT) and its associated RNA (TR). The elongation of telomeric DNA by telomerase depends on the telomerase essential N-terminal (TEN) and C terminal reverse transcriptase (RT) domains. We found that human TEN interacted with single-stranded telomeric DNA and restored function, in trans, to an hTERT mutant lacking hTEN. Telomerase required hTEN residues for activity, telomere maintenance, and extension of cellular replicative lifespan. Two inactive hTERT variants bearing mutations in TEN and RT domains, respectively, cooperated to regenerate telomerase activity in vitro. hTEN interacted with several regions of hTERT suggesting that dimerization may occur via TEN-TERT interactions. The in vivo defect of certain hTEN mutants may involve an inability to interact with factors that recruit the enzyme to the telomere and/or stimulate activity. Human homologs of the S. cerevisiae recruitment factor Est1 interacted with telomerase in a species-specific manner. The TPR domain of hEST1A interacted with the N-terminus of hTERT. The TPR domain of ScEst1 was required for telomere length maintenance by telomerase, and, paradoxically, also negatively regulated telomere length. In preliminary experiments, hTERT interacted with hPOT1/hTPP1. This interaction may stimulate the elongation of telomeres by telomerase. The DNA and protein interactions described herein expand our knowledge of telomerase and present new targets for the manipulation of telomerase function in human disease.

telomeres

telomerase

senescence

DNA binding domain

processivity

reverse transcriptase

0307

0379

Unraveling the ORE1 regulon in Arabidopsis thaliana : molecular and functional characterization of up- and down-stream components

Matallana-Ramírez, Lilian Paola

January 2012

Leaf senescence is an active process required for plant survival, and it is flexibly controlled, allowing plant adaptation to environmental conditions. Although senescence is largely an age-dependent process, it can be triggered by environmental signals and stresses. Leaf senescence coordinates the breakdown and turnover of many cellular components, allowing a massive remobilization and recycling of nutrients from senescing tissues to other organs (e.g., young leaves, roots, and seeds), thus enhancing the fitness of the plant. Such metabolic coordination requires a tight regulation of gene expression. One important mechanism for the regulation of gene expression is at the transcriptional level via transcription factors (TFs). The NAC TF family (NAM, ATAF, CUC) includes various members that show elevated expression during senescence, including ORE1 (ANAC092/AtNAC2) among others. ORE1 was first reported in a screen for mutants with delayed senescence (oresara1, 2, 3, and 11). It was named after the Korean word “oresara,” meaning “long-living,” and abbreviated to ORE1, 2, 3, and 11, respectively. Although the pivotal role of ORE1 in controlling leaf senescence has recently been demonstrated, the underlying molecular mechanisms and the pathways it regulates are still poorly understood. To unravel the signaling cascade through which ORE1 exerts its function, we analyzed particular features of regulatory pathways up-stream and down-stream of ORE1. We identified characteristic spatial and temporal expression patterns of ORE1 that are conserved in Arabidopsis thaliana and Nicotiana tabacum and that link ORE1 expression to senescence as well as to salt stress. We proved that ORE1 positively regulates natural and dark-induced senescence. Molecular characterization of the ORE1 promoter in silico and experimentally suggested a role of the 5’UTR in mediating ORE1 expression. ORE1 is a putative substrate of a calcium-dependent protein kinase named CKOR (unpublished data). Promising data revealed a positive regulation of putative ORE1 targets by CKOR, suggesting the phosphorylation of ORE1 as a requirement for its regulation. Additionally, as part of the ORE1 up-stream regulatory pathway, we identified the NAC TF ATAF1 which was able to transactivate the ORE1 promoter in vivo. Expression studies using chemically inducible ORE1 overexpression lines and transactivation assays employing leaf mesophyll cell protoplasts provided information on target genes whose expression was rapidly induced upon ORE1 induction. First, a set of target genes was established and referred to as early responding in the ORE1 regulatory network. The consensus binding site (BS) of ORE1 was characterized. Analysis of some putative targets revealed the presence of ORE1 BSs in their promoters and the in vitro and in vivo binding of ORE1 to their promoters. Among these putative target genes, BIFUNCTIONAL NUCLEASE I (BFN1) and VND-Interacting2 (VNI2) were further characterized. The expression of BFN1 was found to be dependent on the presence of ORE1. Our results provide convincing data which support a role for BFN1 as a direct target of ORE1. Characterization of VNI2 in age-dependent and stress-induced senescence revealed ORE1 as a key up-stream regulator since it can bind and activate VNI2 expression in vivo and in vitro. Furthermore, VNI2 was able to promote or delay senescence depending on the presence of an activation domain located in its C-terminal region. The plasticity of this gene might include alternative splicing (AS) to regulate its function in different organs and at different developmental stages, particularly during senescence. A model is proposed on the molecular mechanism governing the dual role of VNI2 during senescence. / Der Alterungsprozess lebender Organismen wird seit vielen Jahren wissenschaftlich untersucht. In Pflanzen wird der Alterungsprozess Seneszenz genannt. Er ist für das Überleben der Pflanze von großer Bedeutung. Dennoch ist unser Wissen über die molekularen Mechanismen der Blattseneszenz, dessen komplexe Steuerung und die Wechselwirkungen mit Umweltsignale noch sehr limitiert. Ein wichtiges Steuerungselement besteht in der Aktivierung bestimmter Transkriptionsfaktoren (TFs) die während der Seneszenz unterschiedlich exprimiert werden. Aus der Literatur ist bekannt, dass Mitglieder der NAC TF Familie (NAM/ATAF/CUC) an der Regulation der Seneszenz bei Pflanzen beteiligt sind. ORE1 (ANAC092/AtNAC2), ein NAC TF mit erhöhter Genexpression während der Seneszenz, wurde erstmals in Mutanten mit verzögerte Seneszenz beschrieben, die molekularen Mechanismen, wie ORE1 die Seneszenz kontrolliert und die Stoffwechselwege reguliert, sind aber noch weitgehend unbekannt. Die Arbeiten im Rahmen dieser Dissertation wurden durchgeführt, um einen tieferen Einblick in die Regulationsmechanismen von ORE1 auf natürliche, dunkel induzierte sowie Salzstress-induzierte Seneszenz zu erhalten. Ergebnisse von Untersuchungen an zwei unterschiedlichen Pflanzenspezies (Arabidopsis thalinana und Nicotiana tabacum) deuten auf ein ähnliches Expressionsmuster von ORE1 während der natürlichen als auch der Salz-induzierten Seneszenz hin. In der Promotorregion von ORE1 wurde ein für natürliche Seneszenz charakteristisches Muster identifiziert. In vivo Analysen ergaben darüber hinaus. Hinweise auf zwei weitere ORE1 Regulatoren. Debei handelt es sich umeinen weiteren NAC TF (ATAF1) und (ii) CKOR, einer Calcium-abhängige Protein-Kinase (CDPK).In weiteren Studien wurden sechs Gene identifiziert, die durch ORE1 reguliert werden. In den Promotoren dieser Gene wurden entsprechende Bindestellen für ORE1 lokalisiert. Die ORE1-Bindung an die Promotoren wurde daraufhin sowohl in vitro als auch in vivo verifiziert. Zwei dieser Gene, die BIFUNCTIONAL Nuclease I (BFNI) und VND-Interacting2 (VNI2), wurden zudem auf molekularer und physiologischer Ebene untersucht.

Blattalterung

Transkriptionsfaktor

Regulationsweg

Leaf senescence

transcription factor

regulatory pathway

Life sciences