Inducible Reporter Lines for Tissue-specific Monitoring of Drosophila Circadian Clock Transcriptional Activity.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Lilyan M Mather, Meghan E Cholak, Connor M Morfoot, Katherine C Curro, Jacob Love, Daniel J Cavanaugh
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Abstract

Organisms track time of day through the function of cell-autonomous molecular clocks. In addition to a central clock located in the brain, molecular clocks are present in most peripheral tissues. Circadian clocks are coordinated within and across tissues, but the manner through which this coordination is achieved is not well understood. We reasoned that the ability to track in vivo molecular clock activity in specific tissues of the fruit fly, Drosophila melanogaster, would facilitate an investigation into the relationship between different clock-containing tissues. Previous efforts to monitor clock gene expression in single flies in vivo have used regulatory elements of several different clock genes to dictate expression of a luciferase reporter enzyme, the activity of which can be monitored using a luminometer. Although these reporter lines have been instrumental in our understanding of the circadian system, they generally lack cell specificity, making it difficult to compare molecular clock oscillations between different tissues. Here, we report the generation of several novel lines of flies that allow for inducible expression of a luciferase reporter construct for clock gene transcriptional activity. We find that these lines faithfully report circadian transcription, as they exhibit rhythmic luciferase activity that is dependent on a functional molecular clock. Furthermore, we take advantage of our reporter lines' tissue specificity to demonstrate that peripheral molecular clocks are able to retain rhythmicity for multiple days under constant environmental conditions.

用于组织特异性监测果蝇生物钟转录活性的诱导报告系。
生物体通过细胞自主分子钟的功能来记录一天中的时间。除了位于大脑中的中央时钟外,分子时钟还存在于大多数外周组织中。生物钟在组织内部和组织之间是协调的,但是这种协调是如何实现的还不是很清楚。我们推断,在果蝇的特定组织中追踪体内分子钟活动的能力,将有助于研究不同含时钟组织之间的关系。以前在体内监测单个果蝇生物钟基因表达的努力使用了几种不同生物钟基因的调控元件来指示荧光素酶报告酶的表达,其活性可以使用光度计来监测。尽管这些报告细胞系有助于我们理解昼夜节律系统,但它们通常缺乏细胞特异性,因此难以比较不同组织之间的分子钟振荡。在这里,我们报道了几种新的果蝇系的产生,这些果蝇系允许诱导表达荧光素酶报告结构,用于时钟基因的转录活性。我们发现这些细胞系忠实地报告了昼夜节律转录,因为它们表现出依赖于功能性分子钟的有节奏的荧光素酶活性。此外,我们利用我们的报告细胞系的组织特异性来证明外周分子钟能够在恒定的环境条件下保持数天的节律性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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