dorsal/arxiv
View SchemamicroRNAs may sharpen spatial expression patterns
| Authors | Erel Levine, Peter McHale, Herbert Levine |
|---|---|
| Categories | |
| ArXiv ID | q-bio/0702046 |
| URL | https://arxiv.org/abs/q-bio/0702046 |
| DOI | 10.1371/journal.pcbi.0030233 |
Abstract
The precise layout of gene expression patterns is a crucial step in development. Formation of a sharp boundary between high and low expression domains requires a genetic mechanism which is both sensitive and robust to fluctuations, a demand that may not be easily achieved by morphogens alone. Recently it has been demonstrated that small RNAs (and, in particular, microRNAs) play many roles in embryonic development. While some RNAs are essential for embryogenesis, others are limited to fine-tuning a predetermined gene expression pattern. Here we explore the possibility that small RNAs participate in sharpening a gene expression profile that was crudely established by a morphogen. To this end we study a model where small RNAs interact with a target gene and diffusively move from cell to cell. Though diffusion generally smears spatial expression patterns, we find that intercellular mobility of small RNAs is actually critical in sharpening the interface between target expression domains in a robust manner. We discuss the applicability of our results, as examples, to the case of leaf polarity establishment in maize and Hox patterning in the early {\it Drosophila} embryo. Our findings point out the functional significance of some mechanistic properties, such as mobility of small RNAs and the irreversibility of their interactions. These properties are yet to be established directly for most classes of small RNAs. An indirect yet simple experimental test of the proposed mechanism is suggested in some detail.
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"abstract": "The precise layout of gene expression patterns is a crucial step in\ndevelopment. Formation of a sharp boundary between high and low expression\ndomains requires a genetic mechanism which is both sensitive and robust to\nfluctuations, a demand that may not be easily achieved by morphogens alone.\nRecently it has been demonstrated that small RNAs (and, in particular,\nmicroRNAs) play many roles in embryonic development. While some RNAs are\nessential for embryogenesis, others are limited to fine-tuning a predetermined\ngene expression pattern. Here we explore the possibility that small RNAs\nparticipate in sharpening a gene expression profile that was crudely\nestablished by a morphogen. To this end we study a model where small RNAs\ninteract with a target gene and diffusively move from cell to cell. Though\ndiffusion generally smears spatial expression patterns, we find that\nintercellular mobility of small RNAs is actually critical in sharpening the\ninterface between target expression domains in a robust manner. We discuss the\napplicability of our results, as examples, to the case of leaf polarity\nestablishment in maize and Hox patterning in the early {\\it Drosophila} embryo.\nOur findings point out the functional significance of some mechanistic\nproperties, such as mobility of small RNAs and the irreversibility of their\ninteractions. These properties are yet to be established directly for most\nclasses of small RNAs. An indirect yet simple experimental test of the proposed\nmechanism is suggested in some detail.",
"arxiv_id": "q-bio/0702046",
"authors": [
"Erel Levine",
"Peter McHale",
"Herbert Levine"
],
"categories": [
"q-bio.MN"
],
"doi": "10.1371/journal.pcbi.0030233",
"title": "microRNAs may sharpen spatial expression patterns",
"url": "https://arxiv.org/abs/q-bio/0702046"
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