A new role of the Arabidopsis SEPALLATA3 gene revealed by its constitutive expression

During Arabidopsis flower development a set of homeotic genes plays a central role in specifying the distinct floral organs of the four whorls, sepals in the outermost whorl, and petals, stamens, and carpels in the sequentially inner whorls. The current model for the identity of the floral organs includes the SEPALLATA genes that act in combination with the A, B and C genes for the specification of sepals, petals, stamens and carpels. According to this new model, the floral organ identity proteins would form different complexes of proteins for the activation of the downstream genes. We show that the presence of SEPALLATA proteins is needed to activate the AG downstream gene SHATTERPROOF2, and that SEPALLATA4 alone does not provide with enough SEPALLATA activity for the complex to be functional. Our results suggest that CAULIFLOWER may be part of the protein complex responsible for petal development and that it is fully required in the absence of APETALA1 in 35S::SEP3 plants. In addition, genetic and molecular experiments using plants constitutively expressing SEPALLATA3 revealed a new role of SEPALLATA3 in activating other B and C function genes. We molecularly prove that the ectopic expression of SEPALLATA3 is sufficient to ectopically activate APETALA3 and AGAMOUS. Remarkably, plants that constitutively express both SEPALLATA3 and LEAFY developed ectopic petals, carpels and ovules outside of the floral context.     

Functional analysis of MADS-box genes controlling ovule development in Arabidopsis using the ethanol-inducible alc gene-expression system

In Arabidopsis, different combinations of ABC organ identity proteins interact in the presence of SEPALLATA (SEP) proteins to regulate floral organ differentiation. Ectopic expression of SEP3 in combination with class A and B or B and C genes is sufficient to homeotically convert vegetative leaves into petal-like organs and bracts into stamen-like structures, respectively. Recently, it has been shown that the three MADS-box genes SEEDSTICK (STK), SHATTERPROOF1 (SHP1) and SHP2 act redundantly to control ovule identity. Protein interaction assays performed in yeast in combination with genetic studies demonstrated that these MADS-box factors only interact in the presence of SEP proteins to form complexes that determine ovule differentiation. Here, we address the question whether the ectopic co-expression of ovule identity proteins is sufficient to induce the homeotic conversion of vegetative leaves into carpel-like structures bearing ovules. We present the phenotypic characterization of Arabidopsis plants that ectopically express ovule identity factors under the regulation of the ethanol inducible gene expression system. These experiments indicate that the ectopic co-expression of SEP3 and SHP1 and/or STK is probably not sufficient to homeotically transform vegetative tissues into carpels with ovules. However, comparing the phenotypes obtained by ectopic expression of STK and/or SHP1 with or without SEP3 shows that co-expression of factors that are able to form complexes in yeast cause more extreme homeotic transformations, confirming the functional role of these complexes in vivo.     

Ternary complex formation between the MADS-box proteins SQUAMOSA, DEFICIENS and GLOBOSA is involved in the control of floral architecture in Antirrhinum majus.

In Antirrhinum, floral meristems are established by meristem identity genes. Floral meristems give rise to floral organs in whorls, with their identity established by combinatorial activities of organ identity genes. Double mutants of the floral meristem identity gene SQUAMOSA and organ identity genes DEFICIENS or GLOBOSA produce flowers in which whorled patterning is partially lost. In yeast, SQUA, DEF and GLO proteins form ternary complexes via their C-termini, which in gel-shift assays show increased DNA binding to CArG motifs compared with DEF/GLO heterodimers or SQUA/SQUA homodimers. Formation of ternary complexes by plant MADS-box factors increases the complexity of their regulatory functions and might be the molecular basis for establishment of whorled phyllotaxis and combinatorial interactions of floral organ identity genes.     

HUA1, a regulator of stamen and carpel identities in Arabidopsis, codes for a nuclear RNA binding protein

Stamen and carpel identities are specified by the combinatorial activities of several floral homeotic genes, APETALA3, PISTILLATA, AGAMOUS (AG), SEPALLATA1 (SEP1), SEPALLATA2 (SEP2), and SEPALLATA3 (SEP3), all of which code for MADS domain DNA binding proteins. AG and the SEP genes also control floral determinacy. HUA1 and HUA2 were identified previously as regulators of stamen and carpel identities and floral determinacy because the recessive hua1-1 or hua2-1 allele affected these processes in plants with a lower dosage of functional AG (either homozygous for the weak ag-4 allele or heterozygous for the strong ag-1 allele). HUA2 was cloned previously and shown to code for a novel protein. We isolated the HUA1 gene using a map-based approach and show that it encodes a protein with six CCCH-type zinc finger motifs that is also found in yeast, Caenorhabditis elegans, Drosophila melanogaster, and mammalian proteins. Several such genes from invertebrates and mammals are known to play key regulatory roles in development. Therefore, HUA1 are another example of non-MADS domain proteins involved in organ identity specification. We demonstrated that HUA1 binds ribohomopolymers, preferentially poly rU and poly rG, but not double-stranded DNA in vitro. This finding suggests that HUA1, like several mammalian CCCH zinc finger proteins, is an RNA binding protein. Therefore, HUA1 likely participates in a new regulatory mechanism governing flower development.