Elucidating the Temporal Patterns of Gene Expression in the Inferred Regulatory Interactions of GmCOL1b in Glycine max.

The CONSTANS ( CO ) gene in Arabidopsis thaliana has a central role in photoperiodic regulation of flowering. However, the roles of CO genes in mediating flowering in soybeans ( Glycine max ) remain uncertain. We previously inferred regulatory interactions of a soybean CO homolog, GmCOL1b , using in-house RNA-seq data and the network inference algorithm package CausNet. Here, we identify potential GmCOL1b downstream genes and experimentally verify them by expressing GmCOL1b in soybean protoplast cells. Temporal expression patterns of these genes indicate the regulatory effects of GmCOL1b on the expression of the circadian clock genes GmLCL1 and GmLCL4 and the flowering regulator GmTEM1a .

Clarifying the Temporal Dynamics of the Circadian Clock and Flowering Gene Network Using Overexpression and Targeted Mutagenesis of Soybean EARLY FLOWERING 3-1 ( GmELF3-1 ).

With progressing climate fluctuations, an understanding of the molecular mechanisms of crop plants that regulate their flowering responses to environments is crucial. To achieve this goal, we aimed at clarifying the gene regulatory networks among the circadian clock and flowering genes in soybean ( Glycine max ). Based on our network inference approach , we hypothesize that GmELF3-1 , one of the Evening Complex (EC) gene homologs in soybean's circadian clock, may have an integrative role in transcriptional regulation of the circadian clock and flowering gene network. In this study, we verify GmELF3-1 ' s regulatory roles in its potential downstream genes by modulating the activity of GmELF3-1 using overexpression and CRISPR-Cas9 in soybean protoplasts. Our results indicate that GmELF3-1 may control the expression of the PRR genes in the circadian clock and the flowering gene GmCOL1a .