Global ETD Search

81	Characterization and functional analysis of ZEITLUPE protein in the regulation of the circadian clock and plant development Geng, Ruishuang. January 2006 (has links) Thesis (Ph. D.)--Ohio State University, 2006. / Title from first page of PDF file. Includes bibliographical references (p. 140-154).
82	Modelling genetic regulatory networks : a new model for circadian rhythms in Drosophila and investigation of genetic noise in a viral infection process : a thesis submitted in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Computational Systems Biology at Lincoln University, New Zealand / Xie, Z. January 2007 (has links) Thesis (Ph. D.) -- Lincoln University, 2007. / Also available via the World Wide Web.
83	Chronic Ethanol Modulated Photic and Non-photic Phase Responses in Syrian Hamster and C57BL/6J Inbred Mouse Seggio, Joseph A. January 2009 (has links) (PDF) No description available. Alcohol -- Physiological effect
84	Effects of Neonatal Clomipramine Treatment on Photic and Non-Photic Circadian Phase Shifting in Rats Dwyer, Suzanne January 2000 (has links) (PDF) No description available. Clomipramine
85	Neurotransmitter receptors in the suprachiasmatic nucleus: circadian and developmental studies Robinson, Miqun L. (Miqun Li) 12 1900 (has links) The present audiographic study examined ligands for three receptors, chosen on the basis of high abundance of these receptors in the SCN relative to other brain regions([125I)VIP and [125I) angiotensin II) or the ability of pharmacological manipulations to affect the phase and period of circadian rhythms. circadian rhythms neurotransmitter receptors superchiasmatic nucleus
86	Genetic manipulation of the mammalian circadian clock Smyllie, Nicola Jane January 2014 (has links) No description available.
87	Effect of light on the circadian activity rhythm of the slow loris, Nycticebus coucang Redman, Jimmy F., Jr. 01 January 1979 (has links) In this study, the locomotor activity of a nocturnal prosimian, the slow loris (Nycticebus coucang), was monitored under an experimentally varied light regime. During the process of reversing their day-night cycle, activity was monitored for a light-dark cycle roughly correlating to the external day-night, a free-running period in total darkness followed by a reversed day- night light regime. Under constant conditions an endogenous cycle was shown to be present. During the artificial light regimes, locomotor activity became synchronized to the period of darkness. Lorisidae Behavior Circadian rhythms Life Sciences
88	Eclosion and Locomotor Circadian Rhythms and Differently Entrained to Temperature and Light Cycles in the Flesh Fly Sarcophaga Crassipalpis Ragsdale, Raven, Joplin, Karl, Jones, Thomas C, Ragsdale, Raven 07 April 2022 (has links) Virtually nothing is known about how internal circadian clocks interact with daily environmental cycles in nature. Previous work has shown that temperature and light are both able to successfully entrain (synchronize) circadian rhythms in eclosion (adult emergence) and locomotor activity in Sarcophaga crassipalpis when applied independently. However, much less work has been done to evaluate the relative strength of these Zeitgebers (time cues) when applied simultaneously. In nature, light and temperature cycles generally maintain a fixed relationship with one another, with peak soil and air temperature occurring about three hours after peak brightness each day. By manipulating the relationship between these Zeitgebers this project aims to evaluate the effects of conflicting environmental information on eclosion and locomotor activity rhythms in S. crassipalpis. We measured locomotor and eclosion activity under three temperature/light cycle regimes: 1) in-phase temperature and light cycles, with light and thermophase (warm-period) onset occurring simultaneously, 2) thermophase-delayed, beginning six hours after the onset of photoperiod (light-period), or 3) out-of-phase, with the beginning of photophase corresponding to the end of thermophase. In all experiments, eclosion times are very close to thermophase onset, while locomotor activity does not always hold the same phase position. In fact, in the out-of-phase experiment, locomotor activity is almost entirely synchronized with photophase while eclosion appears to anticipate thermophase onset. These findings suggest that eclosion and locomotor activity rhythms are controlled by different circadian oscillators. This fits with the ecological context of these vital life events. Timing of eclosion is critically important to wing development and the survival of the adult. This process is initiated after being underground, with minimal to no light input, for two weeks – therefore, the most reliable Zeitgeber would be daily soil temperature cycling. As these flies are diurnal, one could reasonably expect light to be the primary Zeitgeber for adult activity, as it is more consistent than temperature cycling. Overall, this implies that an organism’s life history and natural environment must be considered when investigating the circadian clock. Entrainment Zeitgeber temperature Sarcophaga crassipalpis Circadian Rhythms
89	Extraordinary Variation in Circadian Free-Running Periods Observed in Spiders Appears to be Limited to the Superfamily Araneoidea Shepherd, Alexandria E, Jones, Thomas C, Moore, Darrell 07 April 2022 (has links) Almost all organisms have approximately a 24-hour circadian rhythm that enables them to anticipate their environment’s daily rhythmicity. Anticipation increases their likelihood of success in foraging, reproduction, predation, and other life events. Therefore, a disruption of their endogenous clock results in detrimental physiological consequences that significantly impact organisms’ fitness. Surprisingly, we have found numerous spider species with free-running periods that deviate greatly from 24 hours. Free-running period (FRP) is a standard measurement of the period of an organism’s circadian rhythm found by measuring periodicity of behaviors or physiology under constant conditions (e.g., constant darkness and temperature). So far, these extreme spider FRPs have only been observed in the superfamily Araneoidea, but we have only limited sampling of species outside this clade. Therefore, we want to fill this data gap of non-araneoid spiders to deepen our understanding of the evolution of circadian clocks in spiders. Also, we will observe if significant deviation from 24 hours and wide variation in FRP are common to all spider species or are only characteristics of araneoid spiders. Here, we describe the FRPs of four non-araneoid spider species belonging to the RTA clade: Schizocosa avida, Phidippus audax, Agelenopsis pennsylvanica, and Mecaphesa celer. We detected significant free runs (mean + SD) at p<0.001 using Lomb-Scargle periodograms in three out of the four species: S. avida (23.84 ± 1.03 h); P. audax (22.67 ± 0.36 h); and A. pennsylvanica (23.97 ± 0.32 h). However, M. celer was found to be arrhythmic under constant conditions. These findings of near 24-hour FRPs with low deviation among the RTA species, along with previous data, strongly suggest that extreme FRPs are confined to the Araneoidea clade. Thus, we have phylogenetically localized a major evolutionary change in the circadian system of spiders occurring in the Araneoidea clade, approximately 170 million years ago. circadian rhythm phylogenetics evolution spiders Circadian Rhythms
90	Circadian Clock Regulation of the Glycogen Metabolism in Neurospora Crassa Baek, Mokryun January 2018 (has links) No description available. Biology Circadian rhythms Neurospora crassa Glycogen metabolism

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