Dissecting the role of MADS-box genes in monocot floral development and diversity

Mutations in the homeotic gene agamous of the plant Arabidopsis cause the transformation of the floral sex organs. Cloning and sequence analysis of agamous suggest that it encodes a protein with a high degree of sequence similarity to the DNA-binding region of transcription factors from yeast and humans and to the product of a homeotic gene from Antirrhinum. The agamous gene therefore probably encodes a transcription factor that regulates genes determining stamen and carpel development in wild-type flowers.

Genetic studies, using floral homeotic mutants, have led to the ABC model of flower development. This model proposes that the combinatorial action of three sets of genes, the A, B and C function genes, specify the four floral organs (sepals, petals, stamens and carpels) in the concentric floral whorls. However, attempts to convert vegetative organs into floral organs by altering the expression of ABC genes have been unsuccessful. Here we show that the class B proteins of Arabidopsis, PISTILLATA (PI) and APETALA3 (AP3), interact with APETALA1 (AP1, a class A protein) and SEPALLATA3 (SEP3, previously AGL9), and with AGAMOUS (AG, a class C protein) through SEP3. We also show that vegetative leaves of triply transgenic plants, 35S::PI;35S::AP3;35S::AP1 or 35S::PI;35S::AP3;35S::SEP3, are transformed into petaloid organs and that those of 35S::PI;35S::AP3;35S::SEP3;35S::AG are transformed into staminoid organs. Our findings indicate that the formation of ternary and quaternary complexes of ABC proteins may be the molecular basis of the ABC model, and that the flower-specific expression of SEP3 restricts the action of the ABC genes to the flower.

MADS-box genes encode a family of transcription factors which control diverse developmental processes in flowering plants ranging from root to flower and fruit development. Sequencing of (almost) the complete Arabidopsis genome enabled the identification of (almost) all of the Arabidopsis MADS-box genes. MADS-box genes have been divided in two large groups, termed type I and type II genes. The type II genes comprise the MEF2-like genes of animals and fungi and the MIKC-type genes of plants. The majority of MIKC-type genes are of the MIKC(c)-type, which includes all plant MADS-box genes for which expression patterns or mutant phenotypes are known. By phylogeny reconstruction, almost all of the MIKC(c)-type genes can be subdivided into 12 major gene clades, each clade comprising 1-6 paralogs from Arabidopsis and putative orthologs from other seed plants. Here we first briefly describe the deep branching of the MADS-box gene tree to place the MIKC(c)-type genes into an evolutionary context. For every clade of MIKC(c)-type genes we then review what is known about its members from Arabidopsis and well-studied members from other phylogenetically informative plant species. By gene sampling and phylogeny reconstructions we provide minimal estimates for the ages of the different clades. It turns out that 7 of the 12 major gene clades, i.e., AG-, AGL6-, AGL12-, DEF+GLO- (B), GGM13- (B(s)), STMADS11- and TM3-like genes very likely existed already in the most recent common ancestor of angiosperms and gymnosperms about 300MYA. Three of the other clades, i.e., AGL2-, AGL17-, and SQUA-like genes, existed at least already in the most recent common ancestor of monocots and eudicots about 200 MYA. Only for two gene clades, AGL15-like genes (2 genes in Arabidopsis) and FLC-like genes (6 genes) members from plants other than Brassicaceae have not been reported yet. Similarly, only one ancient clade known from other flowering plant species, TM8-like genes, is not represented in Arabidopsis. These findings reveal that the diversity of MADS-box genes in Arabidopsis is rather ancient and representative for other flowering plants. Our studies may thus help to predict the set of MADS-box genes in all other flowering plants, except for relatively young paralogs. For the different gene clades we try to identify ancestral and derived gene functions and review the importance of these clades for seed plant development and evolution. We put special emphasis on gene clades for which insights into their importance has rapidly increased just recently.