The Family of Mads-Box Transcription Factors Controlling Flower Formation in Crocus Sativus L (original) (raw)
Related papers
2004
We have cloned and characterized the structures and expression, of the familiy of flower specific MADS-Box genes of cultivated Crocus (Crocus sativus L). The deduced amino acid sequence of the gene indicated high homology with members of the MADS-box family of transcription factors. In contrast to PISTILLATA (PI) and APETALLA3 (AP3) studies of other plants monocots and dicots and the predictions of the ABC-model for floral organ identity genes, expression studies indicated the presence of the transcripts are not restricted only in the second and third whorl of the flowers but also in the petaloid sepals and stigmata of the mature crocus flower parts, explaining the homeotic transformation of sepals to petals in this species.
Thescientificworldjournal, 2007
Crocus (Crocus sativus L.) is a crop species cultivated for its flowers and, more specifically, for its red stigmas. The flower of crocus is bisexual and sterile, since crocus is a triploid species. Its perianth consists of six petaloid tepals: three tepals in whorl 1 (outer tepals) and three tepals in whorl 2 (inner tepals). The androecium consists of three distinct stamens and the gynoecium consists of a single compound pistil with three carpels, a single three-branched style, and an inferior ovary. The dry form of the stigmas constitutes the commercial saffron used as a food additive, in the coloring industry, and in medicine. In order to uncover and understand the molecular mechanisms controlling flower development in cultivated crocus and its relative wild progenitor species, and characterize a number of crocus flower mutants, we have cloned and characterized different, full-length, cDNA sequences encoding MADS-box transcription factor proteins involved in flower formation.
2010
Crocus sativus L. is a monocot triploid species, member of the family Iridaceae, and is considered to be the highest priced spice in the world. It is cultivated for its flowers and more specifically for its red stigmas. The flower of Crocus is bisexual and it is sterile. The dry form of stigmas constitutes saffron. In order to uncover and understand the molecular mechanisms controlling flower development in cultivated Crocus and its relative wild progenitor species, and characterize a number of Crocus flower mutants we have cloned and characterized different full length cDNA sequences encoding MADS-box transcription factors belonging to the different ABC and E-class MADS box proteins. Herein, we review the isolation of Crocus MADS box genes and primarily discuss their expression patterns in leaves and the four flower organs: outer tepals, inner tepals, stamens and carpels. Expression analysis of the isolated MADS box genes support the hypothesis that a modified ABCDE model in the fl...
Biologia Plantarum, 2005
We have cloned and characterized the expression of Crocus sativus AGAMOUS1 (CsAG1), a putative C-type MADS-box gene homologous to AGAMOUS (AG) from a triploid monocot species crocus (Crocus sativus L.). The typical domain structure of MIKC-type plant MADS proteins was identified. Phylogenetic analysis of the deduced amino acid sequence indicated that the isolated gene forms a clade with the AGAMOUS homologs from the monocots Hyacinthus orientalis and Phalaenopsis equestris. A differential splicing event altering the amino acid sequence at the C terminus was identified, leading to the formation of two mRNAs differing ten nucleotides in size. The presence of both differentially spliced transcripts was restricted only to mature crocus flowers and particularly to stamens and carpels.
DNA Sequence, 2007
For uncovering and understanding the molecular mechanisms controlling flower development in cultivated Crocus sativus and particularly the transformation of sepals in outer whorl (whorl 1) tepals, we have cloned and characterized the expression of a family of five PISTILLATA/GLOBOSA-like (PI/GLO-like) MADS-box genes expressed in the C. sativus flower. The deduced amino acid sequences of the coded proteins indicated high homology with members of the MADS-box family of transcription factors, and particularly with other members of the PI/GLO family of MADS-box proteins that control floral organ identity. PI/GLO expression studies in cultivated C. sativus uncover the presence of PI/GLO transcripts not only in the second and third whorls of flower organs as expected, but also in the outer whorl tepals that are the sepals in most typical flowers. This heterotopic expression of both B-class genes: PI/GLO and AP3/DEF, known to form heterodimers for stamens and petals (petaloid inner whor l-whorl 2-tepals in C. sativus), explains the homeotic transformation of sepals into outer whorl tepals in this species. Analysis of PI/GLO sequences from C. sativus for putative targets to known micro-RNAs (miRNAs) showed that the target site for ath-miRNA167 found in Arabidopsis thaliana PI is not present in C. sativus, however, the PI/GLO sequences may be regulated by an ath-miRNA163.
Journal of Plant Physiology, 2011
To further understand flowering and flower organ formation in the monocot crop saffron crocus (Crocus sativus L.), we cloned four MIKCc type II MADS-box cDNA sequences of the E-class SEPALLATA3 (SEP3) subfamily designated CsatSEP3a/b/c/c_as as well as the three respective genomic sequences. Sequence analysis showed that cDNA sequences of CsatSEP3 c and c_as are the products of alternative splicing of the CsatSEP3c gene. Bioinformatics analysis with putative orthologous sequences from various plant species suggested that all four cDNA sequences encode for SEP3-like proteins with characteristic motifs and amino acids, and highlighted intriguing sequence features. Phylogenetically, the isolated sequences were closest to the SEP3-like genes from monocots such as Asparagus virgatus, Oryza sativa, Zea mays, and the dicot Arabidopsis SEP3 gene. All four isolated C. sativus sequences were strongly expressed in flowers and in all flower organs: whorl1 tepals, whorl2 tepals, stamens and carpels, but not in leaves. Expression of CsatSEP3a/b/c/c_as cDNAs was compared in wild-type and mutant flowers. Expression of the isolatedCsatSEP3-like genes in whorl1 tepals together with E-class CsatAP1/FUL subfamily and B-class CsatAP3 and CsatPI subfamilies of genes, fits the ABCE “quartet model,” an extended form of the original ABC model proposed to explain the homeotic transformation of whorl1 sepals into whorl1 tepals in Liliales and Asparagales plants such as C. sativus. This conclusion was also supported by the interaction of the CsatSEP3b protein with CsatAP1/FUL and CsatAP3 proteins. In contrast, expression of both B-class CsatAP3 and CsatPI genes and the C-class CsatAGAMOUS genes together with E-class CsatSEP3-like genes in carpels, without any phenotypic effects on carpels, raises questions about the role of these gene classes in carpel formation in this non-grass monocot and requires further experimentation. Finally, taking advantage of the size and sequence differences in amplified genomic sequences of the triploid C. sativus and comparing them with the respective sequences from C. tomasii, C. hadriaticus and C. cartwrightianus, three putative wild-type diploid progenitor species, we examined the origin of CsatSEP3a sequence.
Molecular Biology Reports, 2012
Genes in the phosphatidyl-ethanolamine-binding protein (PEBP) family are instrumental in regulating the fate of meristems and flowering time. To investigate the role of these genes in the monocotyledonous plant Crocus (Crocus sativus L), an industrially important crop cultivated for its nutritional and medicinal properties, we have cloned and characterized a CENTRORADIALIS/TERMINAL FLOWER1 (CEN/TFL1) like gene, named CsatCEN/TFL1like, the first reported CEN/TFL1 gene characterized from such a perennial geophyte. Sequence analysis revealed that CsatCEN/TFL1 shows high similarity to its homologous PEBP family genes CEN/TFL1, FT and MFT from a variety of plant species and maintains the same exon/intron organization. Phylogenetic analysis of the CsatCEN/TFL1 amino acid sequence confirmed that the isolated sequences belong to the CEN/TFL1 clade of the PEBP family. CsatCEN/TFL1 transcripts could be detected in corms, flower and flower organs but not in leaves. An alternative spliced transcript was also detected in the flower. Comparison of expression levels of CsatCEN/TFL1 and its alternative spliced transcript in wild type flower and a double flower mutant showed no significant differences. Overexpression of Csat-CEN/TFL1 transcript in Arabidopsis tfl1 plants reversed the phenotype of early flowering and terminal flowering of the tfl1 plants to a normal one. Computational analysis of the obtained promoter sequences revealed, next to common binding motifs in CEN/TFL1-like genes as well as other flowering gene promoters, the presence of two CArG binding sites indicative of control of CEN/TFL1 by MADS-box transcription factors involved in crocus flowering and flower organ formation.
The transcription machinery underlying flower formation
2009
A key step in transcription is the sequence specific binding of transcription factors to their DNA recognition sites. In plants virtually no information is available about the composition of transcription factor complexes. Also DNA recognition and binding is still a mystery. Here we present the first results of the composition of transcription factor complexes and protein-DNA interactions by in vivo measurements. A master role is reserved for the glue protein SEP3, which is required for the formation of the flower and all its organs.