Project description:Oxygen is a key signalling component of plant biology, and whilst an oxygen-sensing mechanism was previously described in Arabidopsis thaliana, key features of the associated PCO N-degron pathway and Group VII ETHYLENE RESPONSE FACTOR (ERFVII) transcription factor substrates remain unknown. We demonstrate that ERFVIIs show non-autonomous activation of root hypoxia tolerance, and are essential for root development and survival under oxygen limiting conditions in the soil. We determine the combined effects of ERFVIIs in controlling genome expression and define genetic and environmental components required for proteasome-dependent oxygen-regulated stability of ERFVIIs through the PCO N-degron pathway. Using a plant extract, unexpected amino-terminal cysteine sulphonic acid oxidation level of ERFVIIs was observed, suggesting a requirement for additional enzymatic activity within the pathway. Our results provide a holistic understanding of the properties, functions and readouts of this oxygen-sensing mechanism defined through its role in modulating ERFVII stability.

Project description:Oxygen is a key signalling component of plant biology and, whilst an oxygen-sensing mechanism was previously described in Arabidopsis thaliana. However, key features of the associated PCO N-degron pathway and Group VII ETHYLENE RESPONSE FACTOR (ERFVII) transcription factor substrates remain unknown. We demonstrate that ERFVIIs show non-autonomous activation of root hypoxia tolerance, and are essential for root development and survival under oxygen limiting conditions in the soil. We determine the combined effects of ERFVIIs in controlling genome expression and define genetic and environmental components required for proteasome-dependent oxygen-regulated stability of ERFVIIs through the PCO N-degron pathway. Using a plant extract, unexpected amino-terminal cysteine oxidation to sulphonic acid oxidation level of ERFVIIs was defined, suggesting a requirement for additional enzymatic activity within the pathway. Our results provide a holistic understanding of the properties, functions and readouts of this oxygen-sensing mechanism defined through its role in modulating ERFVII stability.

Project description:The polycomb repressive complex 2 (PRC2) regulates epigenetic gene repression in eukaryotes. Mechanisms controlling its developmental specificity and signal-responsiveness are poorly understood. Here, we identify an oxygen-sensitive N-terminal (N-) degron in the plant PRC2 subunit VERNALIZATION(VRN)2, a homolog of animal Su(z)12, that promotes its degradation via the N-end rule pathway. We provide evidence that this N-degron arose early during angiosperm evolution via gene duplication and N-terminal truncation, facilitating expansion of PRC2 function in flowering plants. We show that proteolysis via the N-end rule pathway prevents ectopic VRN2 accumulation, and that hypoxia and long-term cold exposure lead to increased VRN2 abundance, which we propose may be due to inhibition of VRN2 turnover via its N-degron. Furthermore, we identify an overlap in the transcriptional responses to hypoxia and prolonged cold, and show that VRN2 promotes tolerance to hypoxia. Our work reveals a mechanism for post-translational regulation of VRN2 stability that could potentially link environmental inputs to the epigenetic control of plant development.

Project description:It is widely accepted that the desmoplastic feature of pancreatic ductal adenocarcinoma (PDAC) and the associated hypoxic microenvironment strongly correlate with a more malignant phenotype that is more resistance to conventional-, targeted- and immuno-therapies. Whether chronic hypoxia in the PDAC stromal gives rise to distinct populations driven by genetics diversity or adoption of distinct phenotypic states in response to low oxygen-tension is poorly understood. To overcome potential selection bias during the establishment of primary 3D organoids lines, single cell dissociated from each surgically resected tumour were split and established directly in 20% O­2 (normoxia) and 1% O2 (hypoxia), yielding cystic and solid organoid morphology respectively. Organoid established under hypoxia (HYPO-PCO) displayed higher expression of EMT-related proteins, a Moffitt basil-like subtype transcriptomes and higher resistance to 5-FU than organoid established under normoxia (NORMO-PCO). Strikingly, while NORMO-PCO subjected to hypoxia displayed the expected gene signatures enriched including inflammatory response, mTORC1 signalling and glycolysis, these signatures were also enriched when compared to HYPO-PCO under hypoxia. This indicates that the two organoid lines captured distinct population from the same tumour which they were derived from. Given recent appreciation for the better understanding of and the ability to target hypoxia to improve PDAC therapeutic responses, this study highlights the importance of our approach to study hypoxic population over the more conventional model which study hypoxic response in organoids established under normoxia.

Project description:Molecular oxygen (O2) is necessary for plant metabolic and physiological processes. Land plants have successfully adapted to a range of habitats characterised by very different dynamics of O2 availability. O2 sensing has been mainly characterised in angiosperms, where it is mediated by the N-Cys branch of the N-degron pathway. We aimed to characterise the transcriptional response to limited oxygen availability (hypoxia) in non-seed plants. We set out to compare the transcriptional response to hypoxia in a range of species that recapitulate the major events in the evolution of land plants: M. polymorpha for Hepatophyta, P. patens for Bryophyta, S. moellendorffii for Lycophyta, E. hyemale and P. vittata for eusporangiate and leptosporangiate Monilophyta. Given the differences in each division’s life cycle, we selected the developmental phase that includes the main photosynthetically active organs, to enable comparability of tissues with similar metabolic features. Therefore, we treated mature sporophytes of Marchantia (n), Selaginella (2n), Equisetum (2n) and Pteris (2n) with 1% O2 in the dark for 8 h, while we subjected Physcomitrium gametophores to the same treatment. Controls were maintained under aerobic conditions (21% O2) in the dark. We extracted total mRNAs and sequenced them using the Illumina technology (cit.) to identify differentially expressed genes. We compared the effect of hypoxia on these five species with the datasets available for photosynthetic sporophytes of angiosperms, Arabidopsis thaliana and Oryza sativa . We observed a different extent of response for these species, where P. patens exhibited the mildest changes, in terms of both number of DEGs and extent of up- and down-regulation. In contrast, Arabidopsis and Rice showed a strong response to the treatment.

Project description:Hypoxia exerts major effects on gene expression, which is reconfigured to meet the needs of the stressed plant. In the recent years the mechanisms of oxygen sensing and transcriptional regulation of a cluster of anaerobic genes was described. We utilized a hypomorphic, post-transcriptional gene silencing defective ARGONAUTE1 (AGO1) mutant, ago1-27, to evaluate the contribution of AGO1 to plant tolerance to submergence and its effects on gene expression.

Project description:All but a few eukaryotes die without oxygen and respond dynamically to changes in the level of oxygen available to them. One ancient oxygen-requiring biochemical pathway in eukaryotes is the pathway for the biosynthesis of sterols, leading to cholesterol in animals and ergosterol in fungi. Mutations in this pathway are a frequent cause of azole drug resistance in pathogenic fungi. The regulatory mechanism for the sterol pathway is also widely conserved between animals and fungi and is centred on a transcription activator, SREBP, that forms part of a sterol-sensing complex. However, in one group of yeasts M-bM-^@M-^S the Saccharomycotina, which includes the major pathogen Candida albicans M-bM-^@M-^S control of the sterol pathway has been taken over by an unrelated regulatory protein, Upc2. We show here by analysis of the yeast Yarrowia lipolytica that the evolutionary switch from SREBP to Upc2 was a two-step process in which Upc2 appeared in an ancestor of Saccharomycotina, and SREBP subsequently degenerated and lost its sterol-regulatory function while retaining an ancient role in filamentation. RNA was isolated from Y. lipolytica wildtype (JMY2900) in normoxia (21% oxygen, 4 biological replicates), wildtype (JMY2900) in hypoxia (1% oxygen, 5 biological replicates), upc2 deletion (SMY2) in hypoxia (1% oxygen, 3 biological replicates), and from sre1 (SMY5, SMY8) deletion in hypoxia (1% oxygen, 2 biological replicates). Gene expression was determined using strand-specific RNA-seq.

Project description:Hierarchical regulation of oxygen-sensing through coupled transducers in Arabidopsis thaliana

Project description:Adaptation to low levels of O2 (hypoxia) is a universal biological feature across metazoans. Yet the underlying mechanisms how different species sense O2 deprivation remain to be deciphered. Here we functionally characterize a novel long non-coding RNA (lncRNA), LOC105369301, which we termed hypoxia-induced lncRNA for PLK1 stabilization or HILPS. HILPS exhibits appreciable basal expression exclusively in a broad range of human normal and cancer cells and is robustly induced by hypoxia inducible factor 1α (HIF1α). HILPS binds PLK1 and sequesters it from proteasome degradation. Stabilized PLK1 directly phosphorylates HIF1α and enhance its stability, constituting a positive feedforward circuit that reinforces oxygen sensing by HIF1α. HILPS inactivation triggers catastrophic adaptation defect during hypoxia in both normal and cancer cells. These findings introduce a mechanism that underlies the HIF1α identity deeply interconnected with PLK1 integrity, and identify the HILPS-PLK1-HIF1α pathway as a crucial oxygen-sensing axis in regulation of human physiological and pathogenic processes.

Project description:Plants are aerobic organisms that rely on molecular oxygen for respiratory energy production. Hypoxic conditions, with oxygen levels ranging between 1% and 5%, usually limit aerobic respiration and affect plant growth and development. Here, we demonstrate that hypoxic microenvironment induced by active cell proliferation during the two-step plant regeneration process intrinsically represses the regeneration competence of callus in Arabidopsis thaliana. Hypoxia-repressed plant regeneration was mediated by the RELATED TO APETALA 2.12 (RAP2.12) protein, a member of the Ethylene Response Factor VII (ERF-VII) family. The hypoxia-activated RAP2.12 protein promoted salicylic acid (SA) biosynthesis and defense responses, inhibiting pluripotency acquisition and de novo shoot regeneration in calli. RAP2.12 could bind directly to the SALICYLIC ACID INDUCTION DEFICIENT 2 (SID2) gene promoter and activate SA biosynthesis, repressing plant regeneration via a PLETHORA (PLT)-dependent pathway. The rap2.12 mutant calli exhibited enhanced shoot regeneration, which was impaired by SA treatment. Taken together, our findings demonstrate that cell proliferation-dependent hypoxic microenvironment reduces cellular pluripotency and plant regeneration through the RAP2.12–SID2 module.