Project description:Libraries obtained from microdissected kidney outer medullary collecting duct from C57Bl6/J mice control or after 3 days potassium-depleted diet. Keywords: other

Project description:Libraries obtained from microdissected kidney outer medullary collecting duct from C57Bl6/J mice control or after 3 days potassium-depleted diet. Keywords: other

Project description:Estrogen-related receptor (ERR) alpha is an orphan nuclear receptor highly expressed in the kidneys. ERRalpha is implicated in renal sodium and potassium homeostasis and blood pressure regulation. We used microarray analysis to identify differentially expressed genes in ERR alpha knockout mice kidneys versus wild-type. The results provide insight on the roles of ERRalpha in the kidney. Three biological replicates of WT and ERRaKO were performed, for a total of 6 samples. 2-3 month old males of each genotype were used.

Project description:In this study we investigated the transcriptional response of the yeast Saccharomyces cerevisiae to potassium starvation. To this end yeast cells were grown for 60 min in media without potassium or in media with a standard potassium concnetration (50 mM KCl). Using Serial Analysis of Gene Expression (SAGE)-tag sequencing the effect of potassium starvation on the transcriptome was determined. 4 samples of cells grown in media without potassium and 4 samples of cells grown in the presence of potassium were analyzed.

Project description:In this study we investigated the transcriptional response of the yeast Saccharomyces cerevisiae to potassium starvation. To this end yeast cells were grown for 60 min in media without potassium or in media with a standard potassium concnetration (50 mM KCl). Using Serial Analysis of Gene Expression (SAGE)-tag sequencing the effect of potassium starvation on the transcriptome was determined.

Project description:<p>The scarcity of potassium resources in farmland soils poses a major challenge to global food security. Wild soybean (Glycine soja), a valuable wild germplasm related to cultivated soybeans, is known for its high-stress resistance and adaptability. This study comprehensively compares two wild soybean ecotypes in terms of growth parameters, photosynthetic physiology, mineral ions and metabolite contents, and gene expression, aiming to clarify the regulatory mechanisms of low potassium stress tolerance in wild soybean seedlings' leaves. Results show that in barren-tolerant wild soybean (GS2), genes involved in potassium ion transport were significantly upregulated. This promotes potassium absorption and transport, maintaining a high K⁺ concentration and K⁺/Na⁺ ratio. Carbohydrate synthesis is enhanced in GS2, with increased sucrose and raffinose accumulation and a more active tricarboxylic acid (TCA) cycle. GS2 also strengthens the ascorbic acid-glutathione (ASA-GSH) cycle, along with promoting salicylic acid and 4-aminobutyric acid GABA synthesis, which boosts antioxidant capacity and reactive oxygen species (ROS) scavenging, maintaining oxidative balance. Under low potassium stress, GS2 accumulates unsaturated fatty acids, enhancing cell-membrane fluidity and providing a stress-resistant structural barrier. Overall, this study provides a basis for developing high-quality wild soybean resources and exploring genes for low potassium stress tolerance, which could contribute to improving cultivated soybeans' adaptability to potassium-deficient soils and ensuring global food production stability.</p>

Project description:M. Berg, J. Plöntzke, S. Leonhard-Marek, K.E. Müller & S. Röblitz. A dynamic model to simulate potassium balance in dairy cows. Journal of Dairy Science 100, 12 (2017). High-performing dairy cows require a particular composition of nutritional ingredients, adapted to their individual requirements and depending on their production status. The optimal dimensioning of minerals in the diet, one being potassium, is indispensable for the prevention of imbalances. Potassium balance in cows is the result of potassium intake, distribution in the organism, and excretion, and it is closely related to glucose and electrolyte metabolism. In this paper, we present a dynamical model for potassium balance in lactating and nonlactating dairy cows based on ordinary differential equations. Parameter values were obtained from clinical trial data and from the literature. To verify the consistency of the model, we present simulation outcomes for 3 different scenarios: potassium balance in (1) nonlactating cows with varying feed intake, (2) nonlactating cows with varying potassium fraction in the diet, and (3) lactating cows with varying milk production levels. The results give insights into the short- and long-term potassium metabolism, providing an important step toward the understanding of the potassium network, the design of prophylactic feed additives, and possible treatment strategies.

Project description:Age-associated decline in mitochondrial membrane potential (MMP) is a ubiquitous aspect of eukaryotic organisms and is associated with many aging-related diseases. However, it is not clear whether this decline is a cause or consequence of aging, and therefore whether interventions to reduce MMP decline are a viable strategy to promote healthier aging and longer lifespans. We developed a screening platform in S. cerevisiae to identify mutations that slowed or abrogated the age-associated decline in MMP. Characterization of the longest-lived mutant revealed that reduced internal potassium increased MMP and extended lifespan. Distinct interventions improved cellular MMP and lifespan: deleting a potassium transporter; altering the balance between kinases and phosphatases that control potassium transporter activity; and reducing available potassium in the environment. Similarly, in isolated mitochondria, reducing the concentration of potassium was sufficient to increase MMP. These data indicate that the most abundant monovalent cation in eukaryotic cells plays a critical role in tuning mitochondrial function, consequently impacting lifespan.

Project description:Age-associated decline in mitochondrial membrane potential (MMP) is a ubiquitous aspect of eukaryotic organisms and is associated with many aging-related diseases. However, it is not clear whether this decline is a cause or consequence of aging, and therefore whether interventions to reduce MMP decline are a viable strategy to promote healthier aging and longer lifespans. We developed a screening platform in S. cerevisiae to identify mutations that slowed or abrogated the age-associated decline in MMP. Characterization of the longest-lived mutant revealed that reduced internal potassium increased MMP and extended lifespan. Distinct interventions improved cellular MMP and lifespan: deleting a potassium transporter; altering the balance between kinases and phosphatases that control potassium transporter activity; and reducing available potassium in the environment. Similarly, in isolated mitochondria, reducing the concentration of potassium was sufficient to increase MMP. These data indicate that the most abundant monovalent cation in eukaryotic cells plays a critical role in tuning mitochondrial function, consequently impacting lifespan.

Project description:Autophagy is a conserved process that recycles cellular contents to promote survival. Although nitrogen starvation is the canonical inducer of autophagy, recent studies have revealed several other nutrients important to this process. In this study, we used a quantitative, high-throughput assay to identify potassium starvation as a new and potent inducer of autophagy. We found that potassium-dependent autophagy requires the core pathway kinases Atg1, Atg5, Vps34, as well as other components of Phosphatidylinositol 3-kinase Complex I. Transmission electron microscopy revealed abundant autophagosome formation in response to both stimuli. RNA sequencing indicated distinct transcriptional responses – nitrogen affects transport of ions such as copper while potassium targets the organization of other cellular components. Thus, nitrogen and potassium share the ability to influence metabolic supply and demand but do so in different ways. Both inputs promote catabolism through bulk autophagy, but inhibit cellular anabolism through distinct mechanisms.