Your search keyword '"Caroline H. Ko"' showing total 9 results

1. Memory for Time of Day (Time Memory) Is Encoded by a Circadian Oscillator and Is Distinct From Other Context Memories

Author

Kevin Sam, Caroline H. Ko, Omar A. Rawashdeh, Martin R. Ralph, and Sean W. Cain

Subjects

Male, Communication, Physiology, Suprachiasmatic nucleus, business.industry, Photoperiod, Period (gene), Circadian clock, Context (language use), Time perception, Memory, Light Cycle, Circadian Clocks, Cricetinae, Physiology (medical), Time Perception, Zeitgeber, Animals, Circadian rhythm, Psychology, business, Neuroscience

Abstract

We report that the neural representation of the time of day (time memory) in golden hamsters involves the setting of a 24-h oscillator that is functionally and anatomically distinct from the circadian clock in the suprachiasmatic nucleus (SCN), but is entrained by the SCN acting as a weak zeitgeber. In hamsters, peak conditioned place avoidance (CPA) was expressed only near the time of day of the learning experience (± 2 h) for the first days after conditioning. On a 14:10 light:dark cycle, with conditioning at the end of the light period (zeitgeber time 11 [ZT11]), CPA behavior, including time of day memory, was retained for more than 18 d. With conditioning in the early day (zeitgeber time 03 [ZT03]), CPA was completely lost after 5 d but reemerged after an additional 6 d, with the peak avoidance time shifted to ZT11. When the entraining light cycle was shifted immediately following learning at either ZT11 or ZT03, with no additional experience in the training apparatus, peak CPA 18 d later was always found at ZT11 on the shifted light cycles. When conditioned at ZT03, then placed into constant dark for 18 cycles, the peak shifted to subjective circadian time 11 (CT11). In all experiments, the peak CPA time was set initially to the time of experience, and was reset subsequently to the end of the subjective day, without memory loss for other context associations. In the absence of an SCN, peak avoidance was not reset. Therefore, time memory is distinct from other context memories, and involves the setting of a non-SCN circadian oscillator. We suggest that circadian oscillators underlying time memory work in concert with the SCN to enable anticipation of critical conditions according to both immediate- and long-term probabilities of where and when important conditions could be encountered again.

Published

2013

2. The mouse Clock mutation reduces circadian pacemaker amplitude and enhances efficacy of resetting stimuli and phase–response curve amplitude

Author

Caroline H. Ko, Andrew C. Schook, Ethan M. Fruechte, Anne Marie Chang, Fred W. Turek, Joseph S. Takahashi, Martha Hotz Vitaterna, Marina P. Antoch, and Ethan D. Buhr

Subjects

Light, Photoperiod, Recombinant Fusion Proteins, Period (gene), Circadian clock, CLOCK Proteins, Cell Cycle Proteins, Mice, Inbred Strains, Motor Activity, Biology, Mice, Biological Clocks, Animals, Oscillating gene, Multidisciplinary, Suprachiasmatic nucleus, Nuclear Proteins, Period Circadian Proteins, Biological Sciences, Molecular biology, Circadian Rhythm, CLOCK, PER2, Gene Expression Regulation, Mutation, Trans-Activators, Suprachiasmatic Nucleus, Transcription Factors, PER1

Abstract

The mouse Clock gene encodes a basic helix–loop–helix-PAS transcription factor, CLOCK, that acts in concert with BMAL1 to form the positive elements of the circadian clock mechanism in mammals. The original Clock mutant allele is a dominant negative (antimorphic) mutation that deletes exon 19 and causes an internal deletion of 51 aa in the C-terminal activation domain of the CLOCK protein. Here we report that heterozygous Clock / + mice exhibit high-amplitude phase-resetting responses to 6-h light pulses (Type 0 resetting) as compared with wild-type mice that have low amplitude (Type 1) phase resetting. The magnitude and time course of acute light induction in the suprachiasmatic nuclei of the only known light-induced core clock genes, Per1 and Per2 , are not affected by the Clock /+ mutation. However, the amplitude of the circadian rhythms of Per gene expression are significantly reduced in Clock homozygous and heterozygous mutants. Rhythms of PER2::LUCIFERASE expression in suprachiasmatic nuclei explant cultures also are reduced in amplitude in Clock heterozygotes. The phase–response curves to changes in culture medium are Type 0 in Clock heterozygotes, but Type 1 in wild types, similar to that seen for light in vivo . The increased efficacy of resetting stimuli and decreased PER expression amplitude can be explained in a unified manner by a model in which the Clock mutation reduces circadian pacemaker amplitude in the suprachiasmatic nuclei.

Published

2006

3. A noncanonical E-box enhancer drives mouse Period2 circadian oscillations in vivo

Author

Suhwan Chang, Phillip L. Lowrey, Caroline H. Ko, Seung Hee Yoo, Eun Joo Song, Choogon Lee, Joseph S. Takahashi, Ook Joon Yoo, Shin Yamazaki, and Ethan D. Buhr

Subjects

Transcription, Genetic, Circadian clock, CLOCK Proteins, Gene Expression, Cell Cycle Proteins, Mice, Transgenic, Enhancer RNAs, E-box, Biology, Cell Line, E-Box Elements, Mice, Basic Helix-Loop-Helix Transcription Factors, Animals, Humans, Luciferases, Promoter Regions, Genetic, Enhancer, Transcription factor, Mice, Knockout, Multidisciplinary, Homozygote, ARNTL Transcription Factors, Nuclear Proteins, Period Circadian Proteins, Biological Sciences, Molecular biology, Mice, Mutant Strains, Circadian Rhythm, Mice, Inbred C57BL, CLOCK, Enhancer Elements, Genetic, Protein Biosynthesis, Trans-Activators, Female, Transcription Factors

Abstract

The mouse Period2 ( mPer2 ) locus is an essential negative-feedback element of the mammalian circadian-clock mechanism. Recent work has shown that mPer2 circadian gene expression persists in both central and peripheral tissues. Here, we analyze the mouse mPer2 promoter and identify a circadian enhancer (E2) with a noncanonical 5′-CACGTT-3′ E-box located 20 bp upstream of the mPer2 transcription start site. The E2 enhancer accounts for most circadian transcriptional drive of the mPer2 locus by CLOCK:BMAL1, is a major site of DNaseI hypersensitivity in this region, and is constitutively bound by a transcriptional complex containing the CLOCK protein. Importantly, the E2 enhancer is sufficient to drive self-sustained circadian rhythms of luciferase activity in central and peripheral tissues from mPer2-E2 :: Luciferase transgenic mice with tissue-specific phase and period characteristics. Last, genetic analysis with mutations in Clock and Bmal1 shows that the E2 enhancer is a target of CLOCK and BMAL1 in vivo .

Published

2005

4. Molecular and Genetic Bases for the Circadian System

Author

Caroline H. Ko and Joseph S. Takahashi

Subjects

Genetics, Light effects on circadian rhythm, Cryptochrome, Suprachiasmatic nucleus, Period (gene), Circadian clock, Circadian rhythm, Biology, Oscillating gene, Neuroscience, Bacterial circadian rhythms

Abstract

Circadian rhythms represent an evolutionarily conserved adaptation to the environment that can be traced back to the earliest life forms. In animals, circadian behavior can be analyzed as an integrated system beginning with genes and leading ultimately to behavioral outputs. In the last decade, the molecular mechanism of circadian clocks has been uncovered by the use of phenotype-driven (forward) genetic analysis in a number of model systems. Circadian oscillations are generated by a set of genes forming a transcriptional autoregulatory feedback loop. Here, the molecular basis of circadian rhythms and the influence of circadian mutations on sleep are reviewed.

Published

2013

5. Emergence of noise-induced oscillations in the central circadian pacemaker

Author

Andrew C. Liu, Eric E. Zhang, Martin R. Ralph, Yujiro Richard Yamada, Joseph S. Takahashi, David K. Welsh, Caroline H. Ko, Steve A. Kay, Ethan D. Buhr, Daniel B. Forger, and Mignot, Emmanuel

Subjects

Circadian clock, Neuroscience/Neural Homeostasis, Cell Communication, Medical and Health Sciences, Quantitative Biology::Cell Behavior, Tissue Culture Techniques, Mice, 0302 clinical medicine, Cyclic AMP, Biology (General), Computer Science::Databases, Mice, Knockout, Neurons, 0303 health sciences, Chronobiology, Suprachiasmatic nucleus, General Neuroscience, Quantitative Biology::Molecular Networks, food and beverages, ARNTL Transcription Factors, Period Circadian Proteins, Biological Sciences, Bacterial circadian rhythms, Circadian Rhythm, PER2, Suprachiasmatic Nucleus, General Agricultural and Biological Sciences, Sleep Research, Research Article, medicine.medical_specialty, endocrine system, QH301-705.5, 1.1 Normal biological development and functioning, Quantitative Biology::Tissues and Organs, Knockout, Computational Biology/Transcriptional Regulation, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Underpinning research, Internal medicine, Circadian Clocks, medicine, Animals, Circadian rhythm, 030304 developmental biology, Stochastic Processes, General Immunology and Microbiology, Quantitative Biology::Neurons and Cognition, Agricultural and Veterinary Sciences, Neurosciences, Endocrinology, Light effects on circadian rhythm, nervous system, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Computational modeling and experimentation explain how intercellular coupling and intracellular noise can generate oscillations in a mammalian neuronal network even in the absence of cell-autonomous oscillators., Bmal1 is an essential transcriptional activator within the mammalian circadian clock. We report here that the suprachiasmatic nucleus (SCN) of Bmal1-null mutant mice, unexpectedly, generates stochastic oscillations with periods that overlap the circadian range. Dissociated SCN neurons expressed fluctuating levels of PER2 detected by bioluminescence imaging but could not generate circadian oscillations intrinsically. Inhibition of intercellular communication or cyclic-AMP signaling in SCN slices, which provide a positive feed-forward signal to drive the intracellular negative feedback loop, abolished the stochastic oscillations. Propagation of this feed-forward signal between SCN neurons then promotes quasi-circadian oscillations that arise as an emergent property of the SCN network. Experimental analysis and mathematical modeling argue that both intercellular coupling and molecular noise are required for the stochastic rhythms, providing a novel biological example of noise-induced oscillations. The emergence of stochastic circadian oscillations from the SCN network in the absence of cell-autonomous circadian oscillatory function highlights a previously unrecognized level of circadian organization., Author Summary The suprachiasmatic nucleus (SCN) is the master circadian pacemaker in mammals that controls and coordinates physiological processes in a daily manner. The SCN is composed of a network of cells, with each cell acting as an autonomous oscillator. In isolated individual cells, timekeeping is not precise because of the inherent randomness in the biochemical reactions within each cell, involving its core clock components. However, in the SCN network, precise rhythms can emerge because of intercellular coupling. In this article, we study a loss-of-function mutation of BMAL1, a core clock component, which eliminates timekeeping in isolated cells. Surprisingly, in both experiments and mathematical simulations, we find that noisy rhythms emerge from the SCN network even in the presence of this BMAL1 mutation. This random yet coordinated timekeeping has not been observed in previous modeling and experimental work and indicates that a network of cells can utilize noise to help compensate for loss of a physiological function. In normal function, the SCN network mitigates any variability observed in individual cellular rhythms and produces a precise and rhythmic network timekeeping signal. When the individual cells are no longer rhythmic, the coupling pathways within the SCN network can propagate stochastic rhythms that are a reflection of both feed-forward coupling mechanisms and intracellular noise. Thus, in a manner analogous to central pattern generators in neural circuits, rhythmicity can arise as an emergent property of the network in the absence of component pacemaker or oscillator cells.

Published

2010

6. Disruption of the clock components CLOCK and BMAL1 leads to hypoinsulinaemia and diabetes

Author

Caroline H. Ko, James P. Lopez, Xiaozhong Wang, Seth D. Crosby, Ethan D. Buhr, Yumiko Kobayashi, Joseph S. Takahashi, Hong Su, Shelley Mo, Martha Hotz Vitaterna, Louis H. Philipson, Lellean JeBailey, Joseph Bass, Chiaki Omura, Christopher A. Bradfield, Biliana Marcheva, Kathryn Moynihan Ramsey, and Ganka Ivanova

Subjects

Blood Glucose, endocrine system, medicine.medical_specialty, Aging, Cell Survival, Circadian clock, CLOCK Proteins, Biology, In Vitro Techniques, Article, 03 medical and health sciences, Diabetes mellitus genetics, Islets of Langerhans, Mice, 0302 clinical medicine, Internal medicine, Glucose Intolerance, Insulin Secretion, medicine, Diabetes Mellitus, Glucose homeostasis, Animals, Insulin, Wakefulness, 030304 developmental biology, Cell Proliferation, Cell Size, 0303 health sciences, Multidisciplinary, Pancreatic islets, Gene Expression Profiling, ARNTL Transcription Factors, Period Circadian Proteins, Glucose Tolerance Test, Insulin oscillation, Circadian Rhythm, ARNTL, Endocrinology, medicine.anatomical_structure, Phenotype, Synaptic Vesicles, Sleep, 030217 neurology & neurosurgery

Abstract

During periods of feeding, pancreatic islets secrete insulin to maintain glucose homeostasis — a rhythmic process that is disturbed in people with diabetes. Experiments in mice now show that the pancreatic islets contain their own biological clock, which orchestrates insulin secretion during the sleep–wake cycle. The transcription factors CLOCK and BMAL1 are vital for this process, and mice with defective copies of the genes Clock and Bmal1 develop hypoinsulinaemia and diabetes. By demonstrating that a local tissue clock integrates circadian and metabolic signals in pancreatic β-cells, this work suggests that circadian analyses are crucial for deeper understanding of metabolic phenotypes, as well as for the treatment of metabolic diseases such as type 2 diabetes. Circadian rhythms control many physiological functions. During periods of feeding, pancreatic islets secrete insulin to maintain glucose homeostasis — a rhythmic process that is disturbed in people with diabetes. These authors show that pancreatic islets contain their own clock: they have self-sustained circadian oscillations of CLOCK and BMAL1 genes and proteins, which are vital for the regulation of circadian rhythms. Without this clock, a cascade of cellular failure and pathology initiates the onset of diabetes mellitus. The molecular clock maintains energy constancy by producing circadian oscillations of rate-limiting enzymes involved in tissue metabolism across the day and night1,2,3. During periods of feeding, pancreatic islets secrete insulin to maintain glucose homeostasis, and although rhythmic control of insulin release is recognized to be dysregulated in humans with diabetes4, it is not known how the circadian clock may affect this process. Here we show that pancreatic islets possess self-sustained circadian gene and protein oscillations of the transcription factors CLOCK and BMAL1. The phase of oscillation of islet genes involved in growth, glucose metabolism and insulin signalling is delayed in circadian mutant mice, and both Clock5,6 and Bmal17 (also called Arntl) mutants show impaired glucose tolerance, reduced insulin secretion and defects in size and proliferation of pancreatic islets that worsen with age. Clock disruption leads to transcriptome-wide alterations in the expression of islet genes involved in growth, survival and synaptic vesicle assembly. Notably, conditional ablation of the pancreatic clock causes diabetes mellitus due to defective β-cell function at the very latest stage of stimulus–secretion coupling. These results demonstrate a role for the β-cell clock in coordinating insulin secretion with the sleep–wake cycle, and reveal that ablation of the pancreatic clock can trigger the onset of diabetes mellitus.

Published

2009

7. Inducible and Reversible Clock Gene Expression in Brain Using the tTA System for the Study of Circadian Behavior

Author

Eun Joo Song, Jason L. Chong, Andrew C. Schook, Amira A. Jyawook, Weimin Song, Caroline H. Ko, Hee Kyung Hong, and Joseph S. Takahashi

Subjects

Cancer Research, lcsh:QH426-470, Light, Physiology, Period (gene), Circadian clock, Genetic Vectors, Molecular Sequence Data, CLOCK Proteins, Mice, Transgenic, Biology, Motor Activity, Biochemistry, Models, Biological, Transactivation, 03 medical and health sciences, Mice, 0302 clinical medicine, Genetics, Animals, Circadian rhythm, Transgenes, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Regulation of gene expression, 0303 health sciences, Behavior, Animal, Suprachiasmatic nucleus, Brain, Genetics and Genomics, Mus (Mouse), Molecular biology, Circadian Rhythm, CLOCK, Mice, Inbred C57BL, lcsh:Genetics, Gene Expression Regulation, Doxycycline, Trans-Activators, 030217 neurology & neurosurgery, Research Article, Neuroscience

Abstract

The mechanism of circadian oscillations in mammals is cell autonomous and is generated by a set of genes that form a transcriptional autoregulatory feedback loop. While these “clock genes” are well conserved among animals, their specific functions remain to be fully understood and their roles in central versus peripheral circadian oscillators remain to be defined. We utilized the in vivo inducible tetracycline-controlled transactivator (tTA) system to regulate Clock gene expression conditionally in a tissue-specific and temporally controlled manner. Through the use of Secretogranin II to drive tTA expression, suprachiasmatic nucleus– and brain-directed expression of a tetO::ClockΔ19 dominant-negative transgene lengthened the period of circadian locomotor rhythms in mice, whereas overexpression of a tetO::Clockwt wild-type transgene shortened the period. Low doses (10 μg/ml) of doxycycline (Dox) in the drinking water efficiently inactivated the tTA protein to silence the tetO transgenes and caused the circadian periodicity to return to a wild-type state. Importantly, low, but not high, doses of Dox were completely reversible and led to a rapid reactivation of the tetO transgenes. The rapid time course of tTA-regulated transgene expression demonstrates that the CLOCK protein is an excellent indicator for the kinetics of Dox-dependent induction/repression in the brain. Interestingly, the daily readout of circadian period in this system provides a real-time readout of the tTA transactivation state in vivo. In summary, the tTA system can manipulate circadian clock gene expression in a tissue-specific, conditional, and reversible manner in the central nervous system. The specific methods developed here should have general applicability for the study of brain and behavior in the mouse., Author Summary Although significant progress has been made in unraveling the molecular mechanism of circadian clocks in mammals, previous work has focused on germline mutations and in vitro methods for analysis. To address the function of clock genes, it is necessary to develop tools to manipulate circadian genes in a conditional and tissue-specific manner in vivo. We report such an approach using the tetracycline transactivator system. Despite the development of the “tet” system in transgenic mice over 10 y ago by Bujard and colleagues, there are still relatively few examples of the successful use of the tet system in the central nervous system. Transgenic expression of the Clock gene in the suprachiasmatic nucleus and brain of mice regulated the period length of circadian locomotor rhythms. These effects could be inhibited by low doses of doxycycline in the drinking water. Importantly, low, but not high, doses of doxycycline were completely reversible and led to a rapid reactivation of the Clock transgenes. In summary, the tetracycline-controlled transactivator system can manipulate circadian clock gene expression in a tissue-specific, conditional, and reversible manner in the central nervous system. The specific methods developed here should have general applicability for the study of brain and behavior in the mouse.

Published

2007

8. Molecular components of the mammalian circadian clock

Author

Caroline H. Ko and Joseph S. Takahashi

Subjects

endocrine system, Circadian clock, Gene Expression, Biology, Mice, Genetics, Animals, Humans, Tissue Distribution, Oscillating gene, Molecular Biology, Genetics (clinical), Feedback, Physiological, NPAS2, Models, Genetic, Suprachiasmatic nucleus, General Medicine, Bacterial circadian rhythms, Cell biology, Circadian Rhythm, CLOCK, Phenotype, Light effects on circadian rhythm, Mutation, Suprachiasmatic Nucleus, sense organs, PER1

Abstract

Circadian rhythms are approximately 24-h oscillations in behavior and physiology, which are internally generated and function to anticipate the environmental changes associated with the solar day. A conserved transcriptional-translational autoregulatory loop generates molecular oscillations of 'clock genes' at the cellular level. In mammals, the circadian system is organized in a hierarchical manner, in which a master pacemaker in the suprachiasmatic nucleus (SCN) regulates downstream oscillators in peripheral tissues. Recent findings have revealed that the clock is cell-autonomous and self-sustained not only in a central pacemaker, the SCN, but also in peripheral tissues and in dissociated cultured cells. It is becoming evident that specific contribution of each clock component and interactions among the components vary in a tissue-specific manner. Here, we review the general mechanisms of the circadian clockwork, describe recent findings that elucidate tissue-specific expression patterns of the clock genes and address the importance of circadian regulation in peripheral tissues for an organism's overall well-being.

Published

2006

9. Intercellular Coupling Confers Robustness against Mutations in the SCN Circadian Clock Network

Author

Steve A. Kay, Inder M. Verma, Caroline H. Ko, Francis J. Doyle, Joseph S. Takahashi, Eric E. Zhang, David K. Welsh, Kirsten Meeker, Oded Singer, Andrew C. Liu, Ethan D. Buhr, Hien G. Tran, and Aaron A. Priest

Subjects

endocrine system, animal structures, Circadian clock, Cell Cycle Proteins, Motor Activity, Biology, Article, General Biochemistry, Genetics and Molecular Biology, MOLNEURO, Mice, Cryptochrome, Biological Clocks, Animals, Cells, Cultured, Neurons, Genetics, Flavoproteins, Biochemistry, Genetics and Molecular Biology(all), Suprachiasmatic nucleus, Nuclear Proteins, Period Circadian Proteins, Fibroblasts, Circadian Rhythm, Cell biology, Cryptochromes, PER2, PER3, Light effects on circadian rhythm, Mutation, Suprachiasmatic Nucleus, sense organs, hormones, hormone substitutes, and hormone antagonists, Transcription Factors, PER1

Abstract

SummaryMolecular mechanisms of the mammalian circadian clock have been studied primarily by genetic perturbation and behavioral analysis. Here, we used bioluminescence imaging to monitor Per2 gene expression in tissues and cells from clock mutant mice. We discovered that Per1 and Cry1 are required for sustained rhythms in peripheral tissues and cells, and in neurons dissociated from the suprachiasmatic nuclei (SCN). Per2 is also required for sustained rhythms, whereas Cry2 and Per3 deficiencies cause only period length defects. However, oscillator network interactions in the SCN can compensate for Per1 or Cry1 deficiency, preserving sustained rhythmicity in mutant SCN slices and behavior. Thus, behavior does not necessarily reflect cell-autonomous clock phenotypes. Our studies reveal previously unappreciated requirements for Per1, Per2, and Cry1 in sustaining cellular circadian rhythmicity and demonstrate that SCN intercellular coupling is essential not only to synchronize component cellular oscillators but also for robustness against genetic perturbations.