Your search keyword '"Schlüter U"' showing total 4 results

1. On the Evolutionary Origin of CAM Photosynthesis.

Author

Bräutigam A, Schlüter U, Eisenhut M, and Gowik U

Subjects

Biological Evolution, Mutation, Plants metabolism, Carbon Cycle, Photosynthesis, Plants genetics

Published

2017

2. Flowering Time-Regulated Genes in Maize Include the Transcription Factor ZmMADS1.

Author

Alter P, Bircheneder S, Zhou LZ, Schlüter U, Gahrtz M, Sonnewald U, and Dresselhaus T

Subjects

Amino Acid Sequence, Down-Regulation, Flowers growth & development, Gene Expression Profiling methods, Meristem genetics, Meristem growth & development, Microscopy, Confocal, Photoperiod, Plant Leaves genetics, Plant Leaves growth & development, Plants, Genetically Modified, RNA Interference, Reverse Transcriptase Polymerase Chain Reaction, Sequence Homology, Amino Acid, Time Factors, Up-Regulation, Zea mays classification, Zea mays growth & development, Flowers genetics, Gene Expression Regulation, Developmental, Gene Expression Regulation, Plant, MADS Domain Proteins genetics, Plant Proteins genetics, Zea mays genetics

Abstract

Flowering time (FTi) control is well examined in the long-day plant Arabidopsis (Arabidopsis thaliana), and increasing knowledge is available for the short-day plant rice (Oryza sativa). In contrast, little is known in the day-neutral and agronomically important crop plant maize (Zea mays). To learn more about FTi and to identify novel regulators in this species, we first compared the time points of floral transition of almost 30 maize inbred lines and show that tropical lines exhibit a delay in flowering transition of more than 3 weeks under long-day conditions compared with European flint lines adapted to temperate climate zones. We further analyzed the leaf transcriptomes of four lines that exhibit strong differences in flowering transition to identify new key players of the flowering control network in maize. We found strong differences among regulated genes between these lines and thus assume that the regulation of FTi is very complex in maize. Especially genes encoding MADS box transcriptional regulators are up-regulated in leaves during the meristem transition. ZmMADS1 was selected for functional studies. We demonstrate that it represents a functional ortholog of the central FTi integrator SUPPRESSOR OF OVEREXPRESSION OF CONSTANS1 (SOC1) of Arabidopsis. RNA interference-mediated down-regulation of ZmMADS1 resulted in a delay of FTi in maize, while strong overexpression caused an early-flowering phenotype, indicating its role as a flowering activator. Taken together, we report that ZmMADS1 represents a positive FTi regulator that shares an evolutionarily conserved function with SOC1 and may now serve as an ideal stating point to study the integration and variation of FTi pathways also in maize., (© 2016 American Society of Plant Biologists. All rights reserved.)

Published

2016

3. Maize source leaf adaptation to nitrogen deficiency affects not only nitrogen and carbon metabolism but also control of phosphate homeostasis.

Author

Schlüter U, Mascher M, Colmsee C, Scholz U, Bräutigam A, Fahnenstich H, and Sonnewald U

Subjects

Amino Acids metabolism, Biomass, Gene Expression Regulation, Plant drug effects, Homeostasis drug effects, Homeostasis genetics, Lipid Metabolism drug effects, Lipid Metabolism genetics, Metabolome genetics, Nitrogen pharmacology, Phenotype, Phylogeny, Plant Growth Regulators metabolism, Plant Leaves growth & development, Plant Leaves metabolism, Principal Component Analysis, RNA, Messenger genetics, RNA, Messenger metabolism, Transcription Factors metabolism, Zea mays drug effects, Zea mays genetics, Zea mays growth & development, Adaptation, Physiological drug effects, Adaptation, Physiological genetics, Carbon metabolism, Nitrogen deficiency, Nitrogen metabolism, Phosphates metabolism, Zea mays physiology

Abstract

Crop plant development is strongly dependent on the availability of nitrogen (N) in the soil and the efficiency of N utilization for biomass production and yield. However, knowledge about molecular responses to N deprivation derives mainly from the study of model species. In this article, the metabolic adaptation of source leaves to low N was analyzed in maize (Zea mays) seedlings by parallel measurements of transcriptome and metabolome profiling. Inbred lines A188 and B73 were cultivated under sufficient (15 mM) or limiting (0.15 mM) nitrate supply for up to 30 d. Limited availability of N caused strong shifts in the metabolite profile of leaves. The transcriptome was less affected by the N stress but showed strong genotype- and age-dependent patterns. N starvation initiated the selective down-regulation of processes involved in nitrate reduction and amino acid assimilation; ammonium assimilation-related transcripts, on the other hand, were not influenced. Carbon assimilation-related transcripts were characterized by high transcriptional coordination and general down-regulation under low-N conditions. N deprivation caused a slight accumulation of starch but also directed increased amounts of carbohydrates into the cell wall and secondary metabolites. The decrease in N availability also resulted in accumulation of phosphate and strong down-regulation of genes usually involved in phosphate starvation response, underlining the great importance of phosphate homeostasis control under stress conditions.

Published

2012

4. Regulation of respiration and the oxygen diffusion barrier in soybean protect symbiotic nitrogen fixation from chilling-induced inhibition and shoots from premature senescence.

Author

van Heerden PD, Kiddle G, Pellny TK, Mokwala PW, Jordaan A, Strauss AJ, de Beer M, Schlüter U, Kunert KJ, and Foyer CH

Subjects

Carbohydrate Metabolism, Carbon Dioxide physiology, Cell Respiration, Darkness, Diffusion, Genotype, Phenotype, Plant Shoots physiology, Glycine max microbiology, Transcription, Genetic, Cold Temperature, Nitrogen Fixation, Oxygen physiology, Root Nodules, Plant physiology, Glycine max physiology, Symbiosis

Abstract

Symbiotic nitrogen fixation is sensitive to dark chilling (7 degrees C-15 degrees C)-induced inhibition in soybean (Glycine max). To characterize the mechanisms that cause the stress-induced loss of nodule function, we examined nodule structure, carbon-nitrogen interactions, and respiration in two soybean genotypes that differ in chilling sensitivity: PAN809 (PAN), which is chilling sensitive, and Highveld Top (HT), which is more chilling resistant. Nodule numbers were unaffected by dark chilling, as was the abundance of the nitrogenase and leghemoglobin proteins. However, dark chilling decreased nodule respiration rates, nitrogenase activities, and NifH and NifK mRNAs and increased nodule starch, sucrose, and glucose in both genotypes. Ureide and fructose contents decreased only in PAN nodules. While the chilling-induced decreases in nodule respiration persisted in PAN even after return to optimal temperatures, respiration started to recover in HT by the end of the chilling period. The area of the intercellular spaces in the nodule cortex and infected zone was greatly decreased in HT after three nights of chilling, an acclimatory response that was absent from PAN. These data show that HT nodules are able to regulate both respiration and the area of the intercellular spaces during chilling and in this way control the oxygen diffusion barrier, which is a key component of the nodule stress response. We conclude that chilling-induced loss of symbiotic nitrogen fixation in PAN is caused by the inhibition of respiration coupled to the failure to regulate the oxygen diffusion barrier effectively. The resultant limitations on nitrogen availability contribute to the greater chilling-induced inhibition of photosynthesis in PAN than in HT.

Published

2008