Project description:225 years ago, Alexander von Humboldt documented his first observations of a peculiar phenomenon in Clusia rosea (Clusiaceae), the first tree known to perform crassulacean acid metabolism (CAM). Since then, the photosynthetic and ecophysiological plasticity of Clusia species have captivated the minds of plant scientists worldwide. CAM is a physiological adaptation to low water availability. While stomata are closed during the day, RuBisCO is supplied with CO2 via decarboxylation of organic acids that have been stored and synthesized during the night by phosphoenolpyruvate carboxylases (PEPC). How the physiological reprogramming necessary for CAM evolved remains enigmatic. Photosynthetic physiotypes of CAM, including weak CAM, inducible CAM, and CAM-cycling have additionally fueled a debate on the evolutionary constraints of CAM and the prospects of engineering CAM into C3 crops. Here, we de novo sequenced the genomes of three Clusia species to capture genetic snapshots along an evo-ecophysiological continuum from weak over inducible to strong CAM. Through a combination of phased chromosome level assembly and annotation, comparative multiomics, and physiological experiments, we demonstrate that diploidization of polyploids explains the physiotype diversity of CAM. We illustrate that Clusia major, a plant that exhibits a C3-type mode of photosynthesis, retained almost all hallmarks of CAM. Transposon-mediated genic diploidization, however, acted upon homoeologs in CAM-related gene families, preferentially those involved in phosphoenolpyruvate (PEP) recycling via phosphorolytic leaf starch metabolization. In effect this rendered a plant capable of constitutive C3+CAM with open stomata during the day by shifting carbohydrate supply (PEP) to viable soluble sugars. Our findings indicate that polyploidization during genus evolution and subsequent diploidization shaped the emergence of extant C3+CAM physiotypes in Clusia. This study of evolutionary intermediates provides crucial insights into the convergent evolution of physiotype diversity and plasticity of CAM.

Project description:<p>225 years ago, Alexander von Humboldt observed the first crassulacean acid metabolism (CAM) tree, Clusia rosea (Clusiaceae). Since then, the photosynthetic and ecophysiological plasticity of Clusia</p><p>species have captivated the minds of plant scientists worldwide. CAM is a physiological adaptation to low water availability. While stomata are closed during the day, RuBisCO is supplied with CO2 via</p><p>decarboxylation of organic acids that have been stored and synthesized during the night by phosphoenolpyruvate carboxylases (PEPC). How the physiological reprogramming necessary for CAM</p><p>evolved remains enigmatic. Photosynthetic physiotypes of CAM, including weak CAM, inducible CAM, and CAM-cycling have additionally fueled a debate on the evolutionary constraints of CAM and the prospects of engineering CAM into C3 crops. Here, we de novo sequenced the genomes of three Clusia species to capture genetic snapshots along an evo-ecophysiological continuum from weak over inducible to strong CAM. Through a combination of phased chromosome level assembly and annotation, comparative multiomics, and physiological experiments, we demonstrate that diploidization of polyploids explains the physiotype diversity of CAM. We illustrate that Clusia major, a plant that exhibits a C3-type mode of photosynthesis, retained almost all hallmarks of CAM. Transposon-mediated genic diploidization, however, acted upon homoeologs in CAM-related gene families, preferentially those involved in phosphoenolpyruvate (PEP) recycling via phosphorolytic leaf starch metabolization. In effect this rendered a plant capable of constitutive C3+CAM with open stomata during the day by shifting carbohydrate supply (PEP) to viable soluble sugars. Our findings indicate that polyploidization during genus evolution and subsequent diploidization shaped the emergence of extant C3+CAM physiotypes in Clusia. This study of evolutionary intermediates provides crucial insights into the convergent evolution of physiotype diversity and plasticity of CAM.</p>

Project description:Climate change and population growth threaten global freshwater resources and food security. Crassulacean acid metabolism (CAM) is a specialized photosynthetic adaptation that exhibits superior water-use efficiency (WUE) compared to C3 and C4 photosynthesis. Mesembryanthemum crystallinum (common ice plant) is capable of shifting from C3 to CAM, making it a key model for investigating the photosynthesis plasticity and its potential to enhance crop stress resilience in a changing climate. To date, the molecular mechanisms underlying this high-WUE photosynthetic transition remain largely unknown.

Project description:We demonstrate that phosphoenolpyruvate (PEP) generally inhibits viral infection in vitro and in vivo. In order to further explore whether PEP controls viral replication through a general mechanism such as enhancing innate response, and if not, what's the critical downstream target(s) of PEP, we performed RNA sequencing (RNA-seq) analysis on the RAW264.7 cells that were pretreated with 250 μM PEP or PBS for 2 hours, and then infected with or without vesicular stomatitis virus (VSV) for 8 hours.

Project description:Soil water deficit (WD) is one of the most important abiotic stresses affecting plant survival and crop yield. Despite its economic relevance, many gaps remain in our understanding of how crops respond to WD, especially concerning the synergistic coordination of molecular and ecophysiological adaptations delaying plant mortality. In this study, we investigated the gene expression imposed by a progressive WD and combined it with measurements pointing to key ecophysiological thresholds in leaves of tomato plants. We uncovered the transcriptomic changes in mature leaves at four stages defined by physiological markers relating to different WD intensities: partial stomatal closure, complete stomatal closure, after leaf wilting, and beginning of embolism development in the veins. By identifying key transcription factors (TFs) across these progressively worsening WD stages, we investigated the timing and impact of ABA-(in)dependent gene regulatory pathways during WD. In addition, we compared the transcriptome in young developing versus mature leaves and explored the physiological mechanisms that may explain the higher tolerance to dehydration in younger leaves. By correlating the transcriptomic changes to precise ecophysiological measurements, the combined dataset will serve as a framework for future studies comparing leaf molecular and physiological responses to WD at specific intensities.

Project description:The C4 pathway is a highly complex trait that increases photosynthetic efficiency in over sixty plant lineages. Although the majority of C4 plants occupy disturbed, arid and nutrient-poor habitats, some grow in high-nutrient, waterlogged conditions. One such example is Echinochloa glabrescens, which is an aggressive weed of rice paddies. We generated comprehensive transcriptome datasets for C4 E. glabrescens and C3 rice to identify genes associated with adaption to waterlogged, nutrient-replete conditions, but also used the data to better understand how C4 photosynthesis operates in these conditions. Similar to arid C4 species, leaves of E. glabrescens exhibited classical Kranz anatomy with lightly lobed mesophyll cells. As with rice and other hygrophytic C3 species, leaves of E. glabrescens accumulated a chloroplastic phosphoenolpyruvate carboxylase protein, albeit at reduced levels relative to rice. We identified a molecular signature associated with C4 photosynthesis in nutrient-replete, waterlogged conditions that is highly similar to those previously reported from C4 plants that grow in more arid conditions. We also identified a cohort of genes that have been subjected to a selective sweep associated with growth in paddy conditions. Overall, this approach highlights the value of using wild species such as weeds to identify adaptions to specific conditions associated with high-yielding crops in agriculture.

Project description:Physiological and molecular evidences have shown earlier that low CO2 might have been a major driving force during the evolution of C4 photosynthesis, not only being a selection pressure but also as a signaling agent. However, a mechanistic linkage between low CO2 and C4 emergence is missing. In this study, using transcriptomics study in model plant Arabidopsis thaliana, we demonstrated that under long-term low CO2 treatments, the up-regulation of C4 related genes were linked to the up-regulation of genes involved in photorespiration, nitrogen assimilation and glycolysis. Plants under low CO2 also showed altered d13C. The carbonic anhydrase (CA), phosphoenolpyruvate carboxylase (PEPC), malate dehydrogenase (MDH), glutamine oxoglutarate aminotransferase (GS-GOGAT), which are required to reassimilate ammonia, were up-regulated under low CO2. Furthermore, under low CO2, genes involved in PEP regeneration from glycolysis were up-regulated while pyruvate orthophosphate dikinase (PPDK) was down-regulated, suggesting a route of PEP regeneration from glycolysis. All these results suggested that under long-term low CO2 treatment, the selection pressure to recapture the released ammonia from the increased photorespiration might have promoted the evolution of mechanisms for generation PEP from glycolysis and enhancement of enzymes catalyzing formation of oxaloacetate, one intermediate which can accept ammonia residue. These adjustments in metabolism provide a mechanistic linkage between low CO2 and evolution of C4 photosynthesis.

Project description:Already a proven mechanism for drought sustainability, crassulacean acid metabolism (CAM) is a specialized type of photosynthesis that maximizes water-use efficiency (WUE) via an inverse (compared to C3 and C4 photosynthesis-performing species) day/night pattern of stomatal closure/opening to shift CO2 uptake to the nighttime, when evapotranspiration rates are low. A systems-level understanding spanning temporal molecular and metabolic controls is needed to define the cellular behavior that confers advantages in water-limited conditions. Here, we report high-resolution temporal behaviors of transcript, protein, and metabolite abundances across a CAM diel cycle and, where applicable, compare those observations to the well-established C3 model plant, Arabidopsis thaliana. A mechanistic finding that emerged is that CAM operates with a shifted altered redox poise relative to Arabidopsis thaliana. Moreover, we identify widespread rescheduled expression for genes associated with signal transduction mechanisms that are presented in guard cells to regulate stomatal opening/closing. Controlled production and degradation of transcript and proteins is a timing mechanism by which to regulate cellular function, yet knowledge of how this molecular timekeeping regulates CAM physiology is unknown. Here, we provide new insight into complex, post-transcriptional and -translational hierarchies that govern CAM in Agave. These data sets together provide a resource that could inform efforts to engineer traits of the more efficient CAM plant into economically valuable C3 crops.

Project description:In stem cell-derived β (SC-β) cells, metabolic abnormalities persist as obstacles to glucose responsiveness and functional maturation, with the primary metabolic bottlenecks yet to be identified. This study demonstrated that restoring pyruvate kinase 1 (PKM1) re-established pyruvate kinase activity, effectively reversing the SC-β-cell identity loss and functional impairment associated with phosphoenolpyruvate (PEP) accumulation. 13C-glucose labeling metabolomics revealed a disruption in glucose-stimulated metabolite production beginning at the glycolytic PEP stage in stem cell-derived islets (SC-islets). Uniquely, elevated PEP prevented glycolytic metabolite-dependent increase of exocytosis and significantly increased intracellular calcium levels through a KATP channel-independent pathway, even under basal glucose condition. Furthermore, exposure to PEP led to downregulated expression of genes involved in the TCA cycle and respiratory electron transport. This PEP accumulation in SC-islets was associated with markedly reduced pyruvate kinase activity. Overexpression of PKM1 rescued the transcriptional changes induced by PEP accumulation and improved both glucose-stimulated calcium responses and insulin secretion. These findings suggest that PKM1 plays a pivotal role in promoting SC-β cell differentiation and functional maturation by regulating PEP metabolism, offering potential improvements for SC-β cell replacement in diabetes treatment.

Project description:Cotyledons and leaf transcriptomes of species of Salsoleae with different photosynthetic types were de novo assembled and analyzed to provide a better understanding of differential gene expression between C3, C2 and C4 species. Total RNA of cotyledons and leaves of different species of Salsoleae with different photosynthetic types (C3 Salsola webbii, C2 Salsola divaricata, C4 Salsola oppositifolia, C4 Hammada scoparia) were isolated with RNeasy Plant Mini Kit (Qiagen) following Standard protocol (January 2011) and including DNase Digestion with RNase-Free DNase Set (Qiagen). 500 ng were used for cDNA library generation conducted with TruSeq RNA Sample Preperation Kit (Illumina Inc.) following Low Sample Protocol (TruSeq RNA Sample Preparation v2 Guide, Illumina Proprietary, Part # 15026495 Rev. C, May 2012). Sequencing of single reads was performed on an Illumina HiSeq2000 platform.