AUTHOR=Gramzow Lydia , Barker Elizabeth , Schulz Christian , Ambrose Barbara , Ashton Neil , Theissen Guenter , Litt Amy 

TITLE=Selaginella Genome Analysis – Entering the “Homoplasy Heaven” of the MADS World

JOURNAL=Frontiers in Plant Science

VOLUME=3

YEAR=2012

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2012.00214

DOI=10.3389/fpls.2012.00214

ISSN=1664-462X

ABSTRACT=<p>In flowering plants, arguably the most significant transcription factors regulating development are MADS-domain proteins, encoded by Type I and Type II MADS-box genes. Type II genes are divided into the MIKC<sup>C</sup> and MIKC* groups. In angiosperms, these types and groups play distinct roles in the development of female gametophytes, embryos, and seeds (Type I); vegetative and floral tissues in sporophytes (MIKC<sup>C</sup>); and male gametophytes (MIKC*), but their functions in other plants are largely unknown. The complete set of MADS-box genes has been described for several angiosperms and a moss, <italic>Physcomitrella patens</italic>. Our examination of the complete genome sequence of a lycophyte, <italic>Selaginella moellendorffii</italic>, revealed 19 putative MADS-box genes (13 Type I, 3 MIKC<sup>C</sup>, and 3 MIKC*). Our results suggest that the most recent common ancestor of vascular plants possessed at least two Type I and two Type II genes. None of the <italic>S. moellendorffii</italic> MIKC<sup>C</sup> genes were identified as orthologs of any floral organ identity genes. This strongly corroborates the view that the clades of floral organ identity genes originated in a common ancestor of seed plants after the lineage that led to lycophytes had branched off, and that expansion of MIKC<sup>C</sup> genes in the lineage leading to seed plants facilitated the evolution of their unique reproductive organs. The number of MIKC* genes and the ratio of MIKC* to MIKC<sup>C</sup> genes is lower in <italic>S. moellendorffii</italic> and angiosperms than in <italic>P. patens</italic>, correlated with reduction of the gametophyte in vascular plants. Our data indicate that Type I genes duplicated and diversified independently within lycophytes and seed plants. Our observations on MADS-box gene evolution echo morphological evolution since the two lineages of vascular plants appear to have arrived independently at similar body plans. Our annotation of MADS-box genes in <italic>S. moellendorffii</italic> provides the basis for functional studies to reveal the roles of this crucial gene family in basal vascular plants.</p>