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Hairy switches and oscillators - reconstructing the zebrafish segmentation clockOswald, Annelie 26 May 2014 (has links) (PDF)
Formation of segments during vertebrate embryogenesis is regulated by a biological clock. Models and experimental data indicate that the core of this clock consists of a cell- autonomous single cell oscillator. This oscillator likely involves a genetic feedback loop of transcriptional repressors belonging to the hairy gene family. In zebrafish, three her genes, her1, hes6 and her7, have been identified as core oscillator components.
The main purpose of this project was to study the molecular mechanism of the hairy gene negative feedback oscillator in single cells. To determine whether a single cell oscillator is part of the zebrafish segmentation clock, a cell dissociation protocol was established to track the expression of Her1 ex vivo. Upon dissociation, Her1 expression continued to oscillate for up to three cycles. The period of oscillations was significantly slower than that of the segmentation clock, but appears to speed up in the presence of serum.
To test whether the hairy gene interactions are sufficient to generate oscillations in single cells, a protocol was established that uses synthetic biology principles to design, construct and characterize hairy gene networks in yeast. First a library of network parts, containing hairy genes, promoters and Her binding sites was generated and subsequently assembled into simple devices to test their functionality in yeast. The three core oscillator components, Her1, Hes6 and Her7, were characterized and optimized for expression in yeast. In the SWITCH-OFF assay, the Her1 protein, modified with a MigED yeast repressor domain, was found to function as a transcriptional repressor in yeast, while Hes6 with the same modification can not.
The dissociation of segmentation clock cells provides the first direct evidence that single cell oscillators exist in zebrafish. In this system, oscillator dynamics can be studied without the interactions of higher level clock components. In parallel, establishing a yeast chassis for hairy gene networks provides a novel technique to directly test predicted oscillator mechanisms by constructing them ’bottom up’.
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Hairy switches and oscillators - reconstructing the zebrafish segmentation clockOswald, Annelie 30 January 2014 (has links)
Formation of segments during vertebrate embryogenesis is regulated by a biological clock. Models and experimental data indicate that the core of this clock consists of a cell- autonomous single cell oscillator. This oscillator likely involves a genetic feedback loop of transcriptional repressors belonging to the hairy gene family. In zebrafish, three her genes, her1, hes6 and her7, have been identified as core oscillator components.
The main purpose of this project was to study the molecular mechanism of the hairy gene negative feedback oscillator in single cells. To determine whether a single cell oscillator is part of the zebrafish segmentation clock, a cell dissociation protocol was established to track the expression of Her1 ex vivo. Upon dissociation, Her1 expression continued to oscillate for up to three cycles. The period of oscillations was significantly slower than that of the segmentation clock, but appears to speed up in the presence of serum.
To test whether the hairy gene interactions are sufficient to generate oscillations in single cells, a protocol was established that uses synthetic biology principles to design, construct and characterize hairy gene networks in yeast. First a library of network parts, containing hairy genes, promoters and Her binding sites was generated and subsequently assembled into simple devices to test their functionality in yeast. The three core oscillator components, Her1, Hes6 and Her7, were characterized and optimized for expression in yeast. In the SWITCH-OFF assay, the Her1 protein, modified with a MigED yeast repressor domain, was found to function as a transcriptional repressor in yeast, while Hes6 with the same modification can not.
The dissociation of segmentation clock cells provides the first direct evidence that single cell oscillators exist in zebrafish. In this system, oscillator dynamics can be studied without the interactions of higher level clock components. In parallel, establishing a yeast chassis for hairy gene networks provides a novel technique to directly test predicted oscillator mechanisms by constructing them ’bottom up’.
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