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Emery, Patrick

One or more keywords matched the following properties of Emery, Patrick

Property	Value
overview	_{Circadian and Circatidal Rhythms} Our environment is constantly changing. The Sun rises and sets every day, causing rhythmic changes in light and temperature. At most latitudes, weather and day length vary as seasons pass. On the coastline, tides rise and fall. Because these environmental cycles occur with precise periodicities, most organisms on Earth have acquired biological clocks that can track and predict them. Organisms can thus adapt and anticipate changes in light intensity, temperature, day length or water level by adjusting their physiology and behavior in a time-dependent manner. Circadian clocks have a period of 24 hours and synchronize to daily environmental cycles. They regulate complex behaviors such as the sleep/wake cycle, as well as metabolism and physiology throughout our body. Their disruption - for instance due to shift work - can have serious detrimental health consequences. Circatidal clocks are found in coastal organisms. They have a period of 12.4 hours and synchronize to tides. Our lab’s overall objective is to elucidate basic molecular and neural mechanisms that underlie circadian and circatidal rhythms, and to understand how biological clocks allow for behavioral adaptations to environmental cycles. Most of our work is performed in Drosophila melanogaster, a fantastic model organism to study the fundamental mechanisms underlying circadian rhythms and one of its critical outputs: sleep. We have also recently started to use Parhyale hawaiensis, a genetically-tractable crustacean, to study circatidal clocks, the mechanisms of which are very poorly understood. For more information, please visit our lab page at: https://www.umassmed.edu/emerylab/
Post Docs	A postdoc position is available to study circadian rhythms in Drosophila. Contact Patrick Emery (patrick.emery@umassmed.edu).
Rotation Projects	Biological clocks play an essential role in the temporal organization of animal physiology and behavior. We combine the powerful genetics of Drosophila with molecular, cell culture and behavioral approaches to obtain a comprehensive view of the mechanisms regulating circadian clocks and one of their critical output: sleep. We also now study the mechanisms enabling marine organisms to anticipate tides. Indeed, we have developed a model organism to study circatidal rhythms: Parhyale hawaiensis. Rotation projects could for example focus on characterizing new candudate post-transcriptional regulators of circadian rhythms, the role of glial genes in the control of sleep, or studying the molecular mechanisms of circatidal clocks.

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overview

_{Circadian and Circatidal Rhythms}

Our environment is constantly changing. The Sun rises and sets every day, causing rhythmic changes in light and temperature. At most latitudes, weather and day length vary as seasons pass. On the coastline, tides rise and fall. Because these environmental cycles occur with precise periodicities, most organisms on Earth have acquired biological clocks that can track and predict them. Organisms can thus adapt and anticipate changes in light intensity, temperature, day length or water level by adjusting their physiology and behavior in a time-dependent manner.

Circadian clocks have a period of 24 hours and synchronize to daily environmental cycles. They regulate complex behaviors such as the sleep/wake cycle, as well as metabolism and physiology throughout our body. Their disruption - for instance due to shift work - can have serious detrimental health consequences. Circatidal clocks are found in coastal organisms. They have a period of 12.4 hours and synchronize to tides. Our lab’s overall objective is to elucidate basic molecular and neural mechanisms that underlie circadian and circatidal rhythms, and to understand how biological clocks allow for behavioral adaptations to environmental cycles. Most of our work is performed in Drosophila melanogaster, a fantastic model organism to study the fundamental mechanisms underlying circadian rhythms and one of its critical outputs: sleep. We have also recently started to use Parhyale hawaiensis, a genetically-tractable crustacean, to study circatidal clocks, the mechanisms of which are very poorly understood.

For more information, please visit our lab page at: https://www.umassmed.edu/emerylab/

Post Docs

A postdoc position is available to study circadian rhythms in Drosophila. Contact Patrick Emery (patrick.emery@umassmed.edu).

Rotation Projects

Biological clocks play an essential role in the temporal organization of animal physiology and behavior. We combine the powerful genetics of Drosophila with molecular, cell culture and behavioral approaches to obtain a comprehensive view of the mechanisms regulating circadian clocks and one of their critical output: sleep. We also now study the mechanisms enabling marine organisms to anticipate tides. Indeed, we have developed a model organism to study circatidal rhythms: Parhyale hawaiensis.

Rotation projects could for example focus on characterizing new candudate post-transcriptional regulators of circadian rhythms, the role of glial genes in the control of sleep, or studying the molecular mechanisms of circatidal clocks.

One or more keywords matched the following items that are connected to Emery, Patrick

Item Type	Name
Academic Article	The cryb mutation identifies cryptochrome as a circadian photoreceptor in Drosophila.
Academic Article	CRY, a Drosophila clock and light-regulated cryptochrome, is a major contributor to circadian rhythm resetting and photosensitivity.
Academic Article	A unique circadian-rhythm photoreceptor.
Academic Article	Drosophila CRY is a deep brain circadian photoreceptor.
Academic Article	Wild-type circadian rhythmicity is dependent on closely spaced E boxes in the Drosophila timeless promoter.
Academic Article	A subset of dorsal neurons modulates circadian behavior and light responses in Drosophila.
Academic Article	Interactions between circadian neurons control temperature synchronization of Drosophila behavior.
Academic Article	Cryptochromes define a novel circadian clock mechanism in monarch butterflies that may underlie sun compass navigation.
Academic Article	Stopping time: the genetics of fly and mouse circadian clocks.
Academic Article	A constant light-genetic screen identifies KISMET as a regulator of circadian photoresponses.
Academic Article	Light and temperature control the contribution of specific DN1 neurons to Drosophila circadian behavior.
Academic Article	The circadian clock gates the intestinal stem cell regenerative state.
Academic Article	A role for Drosophila ATX2 in activation of PER translation and circadian behavior.
Academic Article	Drosophila clock can generate ectopic circadian clocks.
Academic Article	Roles of the two Drosophila CRYPTOCHROME structural domains in circadian photoreception.
Academic Article	Ectopic CRYPTOCHROME renders TIM light sensitive in the Drosophila ovary.
Academic Article	Glia got rhythm.
Academic Article	Circadian rhythms: timing the sense of smell.
Academic Article	Circadian rhythm of temperature preference and its neural control in Drosophila.
Academic Article	Circadian rhythms: An electric jolt to the clock.
Academic Article	KAYAK-a modulates circadian transcriptional feedback loops in Drosophila pacemaker neurons.
Academic Article	GW182 controls Drosophila circadian behavior and PDF-receptor signaling.
Concept	Circadian Rhythm
Academic Article	Morning and evening oscillators cooperate to reset circadian behavior in response to light input.
Academic Article	Studying circadian rhythms in Drosophila melanogaster.
Academic Article	Mutagenesis with Drosophila.
Academic Article	RNA extraction from Drosophila heads.
Academic Article	RNase protection assay.
Academic Article	Protein extraction from Drosophila heads.
Academic Article	miR-124 Regulates the Phase of Drosophila Circadian Locomotor Behavior.
Academic Article	SIK3-HDAC4 signaling regulates Drosophila circadian male sex drive rhythm via modulating the DN1 clock neurons.
Academic Article	Neural Network Interactions Modulate CRY-Dependent Photoresponses in Drosophila.
Academic Article	Reconfiguration of a Multi-oscillator Network by Light in the Drosophila Circadian Clock.
Academic Article	Drosophila Cryptochrome: Variations in Blue.
Academic Article	Drosophila PSI controls circadian period and the phase of circadian behavior under temperature cycle via tim splicing.
Academic Article	Behavioral circatidal rhythms require Bmal1 in Parhyale hawaiensis.
Academic Article	Sensitive Timing: A Reappraisal of Chronobiology's Foundational Texts.
Academic Article	Clocks at sea: the genome-editing tide is rising.
Academic Article	Fly into tranquility: GABA's role in Drosophila sleep.
Academic Article	Cnidarians are CLOCKing in.
Academic Article	Crosstalk between the circatidal and circadian clocks mediates behavioral adaptation to tidal patterns.
Academic Article	Biological rhythms: In the sea, two clocks are better than one.

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circadian rhythms