Your search keyword '"TOR pathway"' showing total 2 results

1. TOR regulates variability of protein synthesis rates.

Author

Basier, Clovis and Nurse, Paul

Subjects

*PROTEIN synthesis, *SINGLE cell proteins, *PROTEIN metabolism, *FLUID control, *CONDITIONED response

Abstract

Cellular processes are subject to inherent variability, but the extent to which cells can regulate this variability has received little investigation. Here, we explore the characteristics of the rate of cellular protein synthesis in single cells of the eukaryote fission yeast. Strikingly, this rate is highly variable despite protein synthesis being dependent on hundreds of reactions which might be expected to average out at the overall cellular level. The rate is variable over short time scales, and exhibits homoeostatic behaviour at the population level. Cells can regulate the level of variability through processes involving the TOR pathway, suggesting there is an optimal level of variability conferring a selective advantage. While this could be an example of bet-hedging, but we propose an alternative explanation: regulated 'loose' control of complex processes of overall cellular metabolism such as protein synthesis, may lead to this variability. This could ensure cells are fluid in control and agile in response to changing conditions, and may constitute a novel organisational principle of complex metabolic cellular systems. Synopsis: How tightly global cellular metabolic processes are regulated remains unclear. Here, single-cell measurements of amino acid acid flux into nascent proteins reveal high variability of cellular protein synthesis in growing eukaryotic fission yeast, suggesting that a genetically-regulated 'loose' control ensures optimal manoeuvrability. Global protein synthesis rates in exponentially-growing unperturbed fission yeast populations exhibit high cell-to-cell variability. Global protein synthesis is dynamic over short time scales, and exhibits homeostatic behaviour at the population level. Genetic modulation of the TOR pathway and cell-cycle controllers modulates protein translation variability. Amino-acid acid flux into nascent proteins is highly variable and TOR-dependent in growing eukaryotic fission yeast. [ABSTRACT FROM AUTHOR]

Published

2024

2. Gibberellic-acid-dependent expression of α-amylase in wheat aleurone cells is mediated by target of rapamycin (TOR) signaling

Author

Sanzhar Alybayev, Izat Smekenov, Aigerim Kuanbay, Dos Sarbassov, and Amangeldy Bissenbaev

Subjects

TOR pathway, Gibberellic acid, α-Amylase, Ribosomal S6 kinase 1, DELLA, Aleurone layer, Botany, QK1-989

Abstract

Target of rapamycin (TOR) signaling is an essential nutrient-dependent pathway controlling cell growth in all eukaryotes. TOR signaling is well characterized in yeast and animals but remains poorly investigated in plants. The hormonal action of gibberellic acid (GA) is a crucial factor for wheat germination by inducing the synthesis of α-amylase in wheat aleurone cells. Here we showed that GA promotes the activation of Triticum aestivum TOR (TaTOR) signaling as evidenced by increased phosphorylation of T. aestivum S6K1 (TaS6K1) on its conserved hydrophobic motif together with proteasomal degradation of growth-inhibitory factor Rht-1. GA-dependent activation of TaTOR signaling led to α-amylase synthesis and Rht-1 proteasomal degradation because both GA-dependent events were sensitive to TaTOR inhibition. Using antibodies specific to TaTOR, we successfully identified the presence of endogenous TaTOR protein in terminally differentiated wheat aleurone layers. Additionally, by examining the rapamycin-sensitive phosphorylation of S6K1 as a reliable indicator of endogenous TOR kinase activity, we demonstrated that the activity of TaTOR in aleurone layers is enhanced by GA. Importantly, this stimulation is not associated with the regulation of either TaTOR transcription or the accumulation of TaTOR protein. In yeast and pull-down assays, a robust interaction between TaS6K1 and the N terminus of Rht-1 (amino acids 1–234) was observed, a finding further supported by co-immunoprecipitation of endogenous Rht-1 and TaS6K1. Furthermore, the administration of mTOR inhibitors significantly attenuated GA-induced degradation of endogenous Rht-1 and prolonged the persistence of the complex formed by these two proteins. We propose that TaTOR-TaS6K1 signaling contributes to GA-dependent wheat germination by mediating α-amylase synthesis and controlling proteasomal degradation of Rht-1 in wheat aleurone cells.

Published

2024