Your search keyword '"Hoyle NP"' showing total 11 results

1. Author Correction: Eukaryotic cell biology is temporally coordinated to support the energetic demands of protein homeostasis.

Author

O'Neill JS, Hoyle NP, Robertson JB, Edgar RS, Beale AD, Peak-Chew SY, Day J, Costa ASH, Frezza C, and Causton HC

Published

2021

2. CRYPTOCHROMES confer robustness, not rhythmicity, to circadian timekeeping.

Author

Putker M, Wong DCS, Seinkmane E, Rzechorzek NM, Zeng A, Hoyle NP, Chesham JE, Edwards MD, Feeney KA, Fischer R, Peschel N, Chen KF, Vanden Oever M, Edgar RS, Selby CP, Sancar A, and O'Neill JS

Subjects

Animals, Cells, Cultured, Cryptochromes deficiency, Cryptochromes genetics, Drosophila melanogaster, Female, Locomotion, Male, Mice, Mice, Inbred C57BL, Period Circadian Proteins genetics, Period Circadian Proteins metabolism, Circadian Rhythm, Cryptochromes metabolism

Abstract

Circadian rhythms are a pervasive property of mammalian cells, tissues and behaviour, ensuring physiological adaptation to solar time. Models of cellular timekeeping revolve around transcriptional feedback repression, whereby CLOCK and BMAL1 activate the expression of PERIOD (PER) and CRYPTOCHROME (CRY), which in turn repress CLOCK/BMAL1 activity. CRY proteins are therefore considered essential components of the cellular clock mechanism, supported by behavioural arrhythmicity of CRY-deficient (CKO) mice under constant conditions. Challenging this interpretation, we find locomotor rhythms in adult CKO mice under specific environmental conditions and circadian rhythms in cellular PER2 levels when CRY is absent. CRY-less oscillations are variable in their expression and have shorter periods than wild-type controls. Importantly, we find classic circadian hallmarks such as temperature compensation and period determination by CK1δ/ε activity to be maintained. In the absence of CRY-mediated feedback repression and rhythmic Per2 transcription, PER2 protein rhythms are sustained for several cycles, accompanied by circadian variation in protein stability. We suggest that, whereas circadian transcriptional feedback imparts robustness and functionality onto biological clocks, the core timekeeping mechanism is post-translational., (© 2021 MRC Laboratory of Molecular Biology. Published under the terms of the CC BY 4.0 license.)

Published

2021

3. Eukaryotic cell biology is temporally coordinated to support the energetic demands of protein homeostasis.

Author

O'Neill JS, Hoyle NP, Robertson JB, Edgar RS, Beale AD, Peak-Chew SY, Day J, Costa ASH, Frezza C, and Causton HC

Subjects

Autophagy physiology, Bioreactors, Circadian Rhythm, Glycogen metabolism, Heat-Shock Response, Ionomycin, Mechanistic Target of Rapamycin Complex 1 metabolism, Metabolomics, Molecular Chaperones, Osmolar Concentration, Osmotic Pressure, Oxygen metabolism, Protein Biosynthesis, Protein Processing, Post-Translational, Proteome, Proteomics, Ribosomes, Yeasts physiology, Energy Metabolism physiology, Eukaryotic Cells physiology, Proteostasis physiology

Abstract

Yeast physiology is temporally regulated, this becomes apparent under nutrient-limited conditions and results in respiratory oscillations (YROs). YROs share features with circadian rhythms and interact with, but are independent of, the cell division cycle. Here, we show that YROs minimise energy expenditure by restricting protein synthesis until sufficient resources are stored, while maintaining osmotic homeostasis and protein quality control. Although nutrient supply is constant, cells sequester and store metabolic resources via increased transport, autophagy and biomolecular condensation. Replete stores trigger increased H + export which stimulates TORC1 and liberates proteasomes, ribosomes, chaperones and metabolic enzymes from non-membrane bound compartments. This facilitates translational bursting, liquidation of storage carbohydrates, increased ATP turnover, and the export of osmolytes. We propose that dynamic regulation of ion transport and metabolic plasticity are required to maintain osmotic and protein homeostasis during remodelling of eukaryotic proteomes, and that bioenergetic constraints selected for temporal organisation that promotes oscillatory behaviour.

Published

2020

4. Insulin/IGF-1 Drives PERIOD Synthesis to Entrain Circadian Rhythms with Feeding Time.

Author

Crosby P, Hamnett R, Putker M, Hoyle NP, Reed M, Karam CJ, Maywood ES, Stangherlin A, Chesham JE, Hayter EA, Rosenbrier-Ribeiro L, Newham P, Clevers H, Bechtold DA, and O'Neill JS

Subjects

Animals, Circadian Rhythm physiology, Female, Insulin metabolism, Insulin-Like Growth Factor I metabolism, Male, Mammals metabolism, Mice, Mice, Inbred C57BL, Receptor, IGF Type 1 metabolism, Signal Transduction, Circadian Clocks physiology, Feeding Behavior physiology, Period Circadian Proteins metabolism

Abstract

In mammals, endogenous circadian clocks sense and respond to daily feeding and lighting cues, adjusting internal ∼24 h rhythms to resonate with, and anticipate, external cycles of day and night. The mechanism underlying circadian entrainment to feeding time is critical for understanding why mistimed feeding, as occurs during shift work, disrupts circadian physiology, a state that is associated with increased incidence of chronic diseases such as type 2 (T2) diabetes. We show that feeding-regulated hormones insulin and insulin-like growth factor 1 (IGF-1) reset circadian clocks in vivo and in vitro by induction of PERIOD proteins, and mistimed insulin signaling disrupts circadian organization of mouse behavior and clock gene expression. Insulin and IGF-1 receptor signaling is sufficient to determine essential circadian parameters, principally via increased PERIOD protein synthesis. This requires coincident mechanistic target of rapamycin (mTOR) activation, increased phosphoinositide signaling, and microRNA downregulation. Besides its well-known homeostatic functions, we propose insulin and IGF-1 are primary signals of feeding time to cellular clocks throughout the body., (Copyright © 2019 MRC Laboratory of Molecular Biology. Published by Elsevier Inc. All rights reserved.)

Published

2019

5. Daily magnesium fluxes regulate cellular timekeeping and energy balance.

Author

Feeney KA, Hansen LL, Putker M, Olivares-Yañez C, Day J, Eades LJ, Larrondo LF, Hoyle NP, O'Neill JS, and van Ooijen G

Subjects

Adenosine Triphosphate metabolism, Animals, Cell Line, Chlorophyta cytology, Chlorophyta metabolism, Circadian Clocks genetics, Circadian Rhythm genetics, Feedback, Physiological, Gene Expression Regulation, Humans, Intracellular Space metabolism, Male, Mice, TOR Serine-Threonine Kinases metabolism, Time Factors, Circadian Clocks physiology, Circadian Rhythm physiology, Energy Metabolism, Magnesium metabolism

Abstract

Circadian clocks are fundamental to the biology of most eukaryotes, coordinating behaviour and physiology to resonate with the environmental cycle of day and night through complex networks of clock-controlled genes. A fundamental knowledge gap exists, however, between circadian gene expression cycles and the biochemical mechanisms that ultimately facilitate circadian regulation of cell biology. Here we report circadian rhythms in the intracellular concentration of magnesium ions, [Mg(2+)]i, which act as a cell-autonomous timekeeping component to determine key clock properties both in a human cell line and in a unicellular alga that diverged from each other more than 1 billion years ago. Given the essential role of Mg(2+) as a cofactor for ATP, a functional consequence of [Mg(2+)]i oscillations is dynamic regulation of cellular energy expenditure over the daily cycle. Mechanistically, we find that these rhythms provide bilateral feedback linking rhythmic metabolism to clock-controlled gene expression. The global regulation of nucleotide triphosphate turnover by intracellular Mg(2+) availability has potential to impact upon many of the cell's more than 600 MgATP-dependent enzymes and every cellular system where MgNTP hydrolysis becomes rate limiting. Indeed, we find that circadian control of translation by mTOR is regulated through [Mg(2+)]i oscillations. It will now be important to identify which additional biological processes are subject to this form of regulation in tissues of multicellular organisms such as plants and humans, in the context of health and disease.

Published

2016

6. Granules harboring translationally active mRNAs provide a platform for P-body formation following stress.

Author

Lui J, Castelli LM, Pizzinga M, Simpson CE, Hoyle NP, Bailey KL, Campbell SG, and Ashe MP

Subjects

Amino Acids deficiency, Cycloheximide pharmacology, Gene Expression Regulation, Fungal drug effects, Glucose deficiency, RNA Stability drug effects, RNA, Messenger genetics, RNA, Messenger metabolism, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Cytoplasmic Granules metabolism, Protein Biosynthesis drug effects, Saccharomyces cerevisiae metabolism, Stress, Physiological drug effects

Abstract

The localization of mRNA to defined cytoplasmic sites in eukaryotic cells not only allows localized protein production but also determines the fate of mRNAs. For instance, translationally repressed mRNAs localize to P-bodies and stress granules where their decay and storage, respectively, are directed. Here, we find that several mRNAs are localized to granules in unstressed, actively growing cells. These granules play a key role in the stress-dependent formation of P-bodies. Specific glycolytic mRNAs are colocalized in multiple granules per cell, which aggregate during P-body formation. Such aggregation is still observed under conditions or in mutants where P-bodies do not form. In unstressed cells, the mRNA granules appear associated with active translation; this might enable a coregulation of protein expression from the same pathways or complexes. Parallels can be drawn between this coregulation and the advantage of operons in prokaryotic systems., (Copyright © 2014 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2014

7. Circadian rhythms: hijacking the cyanobacterial clock.

Author

Hoyle NP and O'Neill JS

Subjects

Gene Expression Regulation, Bacterial, Hydrogen chemistry, Hydrogenase genetics, Multigene Family genetics, Phosphorylation, Promoter Regions, Genetic, Bacterial Proteins genetics, Circadian Rhythm, Circadian Rhythm Signaling Peptides and Proteins genetics, Hydrogenase metabolism, Synechococcus enzymology

Abstract

Using basic research to advance a practical application, a recent study demonstrates that the circadian clock in cyanobacteria can be 'reprogrammed' to improve yields of heterologous protein production - a green future surely beckons., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

8. Transcript processing and export kinetics are rate-limiting steps in expressing vertebrate segmentation clock genes.

Author

Hoyle NP and Ish-Horowicz D

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Cell Line, Chick Embryo, Glycosyltransferases metabolism, In Situ Hybridization, Fluorescence, Intracellular Signaling Peptides and Proteins, Mice, Proteins metabolism, RNA Splicing physiology, Species Specificity, Time Factors, Zebrafish, Biological Clocks physiology, Body Patterning physiology, Gene Expression Regulation, Developmental physiology, Models, Biological

Abstract

Sequential production of body segments in vertebrate embryos is regulated by a molecular oscillator (the segmentation clock) that drives cyclic transcription of genes involved in positioning intersegmental boundaries. Mathematical modeling indicates that the period of the clock depends on the total delay kinetics of a negative feedback circuit, including those associated with the synthesis of transcripts encoding clock components [Lewis J (2003) Curr Biol 13(16):1398-1408]. Here, we measure expression delays for three transcripts [Lunatic fringe, Hes7/her1, and Notch-regulated-ankyrin-repeat-protein (Nrarp)], that cycle during segmentation in the zebrafish, chick, and mouse, and provide in vivo measurements of endogenous splicing and export kinetics. We show that mRNA splicing and export are much slower than transcript elongation, with the longest delay (about 16 min in the mouse) being due to mRNA export. We conclude that the kinetics of mRNA and protein production and destruction can account for much of the clock period, and provide strong support for delayed autorepression as the underlying mechanism of the segmentation clock.

Published

2013

9. Glucose depletion inhibits translation initiation via eIF4A loss and subsequent 48S preinitiation complex accumulation, while the pentose phosphate pathway is coordinately up-regulated.

Author

Castelli LM, Lui J, Campbell SG, Rowe W, Zeef LA, Holmes LE, Hoyle NP, Bone J, Selley JN, Sims PF, and Ashe MP

Subjects

Adaptation, Physiological genetics, Cluster Analysis, Eukaryotic Initiation Factor-2B metabolism, Eukaryotic Initiation Factor-4G metabolism, Gene Expression, Gene Expression Profiling, Gene Expression Regulation, Fungal, Models, Genetic, Oligonucleotide Array Sequence Analysis, Protein Binding, Protein Stability, RNA, Messenger genetics, RNA, Messenger metabolism, Saccharomyces cerevisiae physiology, Stress, Physiological, Eukaryotic Initiation Factor-4A metabolism, Glucose deficiency, Multiprotein Complexes metabolism, Pentose Phosphate Pathway, Peptide Chain Initiation, Translational, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Up-Regulation

Abstract

Cellular stress can globally inhibit translation initiation, and glucose removal from yeast causes one of the most dramatic effects in terms of rapidity and scale. Here we show that the same rapid inhibition occurs during yeast growth as glucose levels diminish. We characterize this novel regulation showing that it involves alterations within the 48S preinitiation complex. In particular, the interaction between eIF4A and eIF4G is destabilized, leading to a temporary stabilization of the eIF3-eIF4G interaction on the 48S complex. Under such conditions, specific mRNAs that are important for the adaptation to the new conditions must continue to be translated. We have determined which mRNAs remain translated early after glucose starvation. These experiments enable us to provide a physiological context for this translational regulation by ascribing defined functions that are translationally maintained or up-regulated. Overrepresented in this class of mRNA are those involved in carbohydrate metabolism, including several mRNAs from the pentose phosphate pathway. Our data support a hypothesis that a concerted preemptive activation of the pentose phosphate pathway, which targets both mRNA transcription and translation, is important for the transition from fermentative to respiratory growth in yeast.

Published

2011

10. Stress-dependent relocalization of translationally primed mRNPs to cytoplasmic granules that are kinetically and spatially distinct from P-bodies.

Author

Hoyle NP, Castelli LM, Campbell SG, Holmes LE, and Ashe MP

Subjects

Biological Transport, Kinetics, Models, Genetic, Protein Biosynthesis, Cytoplasmic Granules metabolism, Glucose metabolism, Ribonucleoproteins metabolism, Saccharomyces cerevisiae metabolism

Abstract

Cytoplasmic RNA granules serve key functions in the control of messenger RNA (mRNA) fate in eukaryotic cells. For instance, in yeast, severe stress induces mRNA relocalization to sites of degradation or storage called processing bodies (P-bodies). In this study, we show that the translation repression associated with glucose starvation causes the key translational mediators of mRNA recognition, eIF4E, eIF4G, and Pab1p, to resediment away from ribosomal fractions. These mediators then accumulate in P-bodies and in previously unrecognized cytoplasmic bodies, which we define as EGP-bodies. Our kinetic studies highlight the fundamental difference between EGP- and P-bodies and reflect the complex dynamics surrounding reconfiguration of the mRNA pool under stress conditions. An absence of key mRNA decay factors from EGP-bodies points toward an mRNA storage function for these bodies. Overall, this study highlights new potential control points in both the regulation of mRNA fate and the global control of translation initiation.

Published

2007

11. Dynamic cycling of eIF2 through a large eIF2B-containing cytoplasmic body: implications for translation control.

Author

Campbell SG, Hoyle NP, and Ashe MP

Subjects

Blotting, Western, Eukaryotic Initiation Factor-2 genetics, Eukaryotic Initiation Factor-2B genetics, Fluorescence Recovery After Photobleaching, Fluorescent Antibody Technique, Indirect, Green Fluorescent Proteins metabolism, In Situ Hybridization, Fluorescence, Kinetics, Microscopy, Confocal, RNA, Transfer, Met metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae Proteins genetics, Eukaryotic Initiation Factor-2 metabolism, Eukaryotic Initiation Factor-2B metabolism, Inclusion Bodies metabolism, Protein Biosynthesis, Saccharomyces cerevisiae Proteins metabolism

Abstract

The eukaryotic translation initiation factor 2B (eIF2B) provides a fundamental controlled point in the pathway of protein synthesis. eIF2B is the heteropentameric guanine nucleotide exchange factor that converts eIF2, from an inactive guanosine diphosphate-bound complex to eIF2-guanosine triphosphate. This reaction is controlled in response to a variety of cellular stresses to allow the rapid reprogramming of cellular gene expression. Here we demonstrate that in contrast to other translation initiation factors, eIF2B and eIF2 colocalize to a specific cytoplasmic locus. The dynamic nature of this locus is revealed through fluorescence recovery after photobleaching analysis. Indeed eIF2 shuttles into these foci whereas eIF2B remains largely resident. Three different strategies to decrease the guanine nucleotide exchange function of eIF2B all inhibit eIF2 shuttling into the foci. These results implicate a defined cytoplasmic center of eIF2B in the exchange of guanine nucleotides on the eIF2 translation initiation factor. A focused core of eIF2B guanine nucleotide exchange might allow either greater activity or control of this elementary conserved step in the translation pathway.

Published

2005