Machine Learning Inference of Gene Regulatory Networks in Developing <i>Mimulus</i> Seeds

Machine Learning Inference of Gene Regulatory Networks in Developing <i>Mimulus</i> Seeds

The angiosperm seed represents a critical evolutionary breakthrough that has been shown to propel the reproductive success and radiation of flowering plants. Seeds promote the rapid diversification of angiosperms by establishing postzygotic reproductive barriers, such as hybrid seed inviability. Whi...

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Bibliographic Details
Main Authors: Albert Tucci, Miguel A. Flores-Vergara, Robert G. Franks
Format: Article
Language:English
Published: MDPI AG 2024-11-01
Series:Plants
Subjects:
endosperm
embryo
hybrid seed inviability
seed development
postzygotic reproductive barriers
<i>Mimulus erythranthe</i>
Online Access:https://www.mdpi.com/2223-7747/13/23/3297
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Summary:The angiosperm seed represents a critical evolutionary breakthrough that has been shown to propel the reproductive success and radiation of flowering plants. Seeds promote the rapid diversification of angiosperms by establishing postzygotic reproductive barriers, such as hybrid seed inviability. While prezygotic barriers to reproduction tend to be transient, postzygotic barriers are often permanent and therefore can play a pivotal role in facilitating speciation. This property of the angiosperm seed is exemplified in the <i>Mimulus</i> genus. In order to further the understanding of the gene regulatory mechanisms important in the <i>Mimulus</i> seed, we performed gene regulatory network (GRN) inference analysis by using time-series RNA-seq data from developing hybrid seeds from a viable cross between <i>Mimulus guttatus</i> and <i>Mimulus pardalis</i>. GRN inference has the capacity to identify active regulatory mechanisms in a sample and highlight genes of potential biological importance. In our case, GRN inference also provided the opportunity to uncover active regulatory relationships and generate a reference set of putative gene regulations. We deployed two GRN inference algorithms—RTP-STAR and KBoost—on three different subsets of our transcriptomic dataset. While the two algorithms yielded GRNs with different regulations and topologies when working with the same data subset, there was still significant overlap in the specific gene regulations they inferred, and they both identified potential novel regulatory mechanisms that warrant further investigation.
ISSN:2223-7747

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