Rosa Menéndez Castillo scite author profile

Flowering of many plants is induced by environmental signals, but these responses can depend on the age of the plant. Exposure of Arabidopsis thaliana to vernalization (winter temperatures) at germination induces flowering, whereas a close perennial relative Arabis alpina only responds if exposed when at least 5 weeks old. We show that vernalization of these older A. alpina plants reduces expression of the floral repressor PEP1 and activates the orthologs of the Arabidopsis flowering genes SOC1 (Aa SOC1) and LFY (Aa LFY). By contrast, when younger plants are vernalized, PEP1 and Aa SOC1 mRNA levels change as in older plants, but Aa LFY is not expressed. We demonstrate that A. alpina TFL1 (Aa TFL1) blocks flowering and prevents Aa LFY expression when young plants are exposed to vernalization. In addition, in older plants, Aa TFL1 increases the duration of vernalization required for Aa LFY expression and flowering. Aa TFL1 has similar functions in axillary shoots, thus ensuring that following a flowering episode vegetative branches are maintained to continue the perennial life cycle. We propose that Aa TFL1 blocks flowering of young plants exposed to vernalization by setting a threshold for a flowering pathway that is increased in activity as the shoot ages, thus contributing to several perennial traits.

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A conserved microRNA module exerts homeotic control over Petunia hybrida and Antirrhinum majus floral organ identity

Cartolano

et al. 2007

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It is commonly thought that deep phylogenetic conservation of plant microRNAs (miRNAs) and their targets 1,2 indicates conserved regulatory functions. We show that the blind (bl) mutant of Petunia hybrida 3 and the fistulata (fis) mutant of Antirrhinum majus 4,5 , which have similar homeotic phenotypes, are recessive alleles of two homologous miRNA-encoding genes. The BL and FIS genes control the spatial restriction of homeotic class C genes 6,7 to the inner floral whorls, but their ubiquitous early floral expression patterns are in contradiction with a potential role in patterning C gene expression. We provide genetic evidence for the unexpected function of the MIRFIS and MIRBL genes in the center of the flower and propose a dynamic mechanism underlying their regulatory role. Notably, Arabidopsis thaliana, a more distantly related species, also contains this miRNA module but does not seem to use it to confine early C gene expression to the center of the flower.The spatial partitioning of floral homeotic gene expression is crucial for wild-type flower development. Several transcription factors participate in this control, which aims at transcriptional silencing of the so-called 'C genes' outside their genuine expression domain in the inner two whorls of the flower, where they govern reproductive organ (stamen and carpel) development 6,7 . The functions of orthologous repressor genes, constituting the A function of the floral ABCs 6 , are, in part, comparable between different species 8 , as are some of the cis-acting regulatory regions within the large second intron of their structurally and functionally related target C genes AGAMOUS (AG) in Arabidopsis thaliana 7 , pMADS3 in P. hybrida 9 and PLENA and FARINELLI (PLE and FAR) in A. majus 10 . There are also exceptions to these overall similarities among species. For instance, orthologs of the A. thaliana APETALA2 (AP2) gene have no role in C gene regulation in P. hybrida 11 or A. majus 12 , raising the question of whether other genes fulfill this role. Candidates are the BL gene in P. hybrida and FIS in A. majus, which, when mutated, show markedly similar homeotically converted stamenoid petals in their second floral whorls 4,5 (Fig. 1).By a combination of transposon tagging and map-based cloning strategies, we cloned the BL and FIS genes and found that they encode homologous bona fide miRNAs (miRBL and miRFIS), related in their core sequences to members of the large miR169 family 13,14 (Fig. 2). The bl-1 and fis-1 alleles lie within large genomic deletions and thus represent null alleles; bl-2 and fis-2 are transposon induced and genetically unstable alleles (Fig. 2a). miRNA-encoding genes are relatively small targets for mutation, and therefore, recessive mutants are infrequent; bl and fis thus offer a rare opportunity to study and compare the function of potential orthologs in two plant species. miRNAs control gene expression by recognizing short complementary sequences in their transcripts (miRNA-recognition elements, or MREs), which are then post-transcrip...

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Evolution in Action: Following Function in Duplicated Floral Homeotic Genes

Castillo²,

et al. 2005

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Gene duplication plays a fundamental role in evolution by providing the genetic material from which novel functions can arise. Newly duplicated genes can be maintained by subfunctionalization (the duplicated genes perform different aspects of the original gene's function) and/or neofunctionalization (one of the genes acquires a novel function). PLENA in Antirrhinum and AGAMOUS in Arabidopsis are the canonical C-function genes that are essential for the specification of reproductive organs. These functionally equivalent genes encode closely related homeotic MADS-box transcription factors. Using genome synteny, we confirm phylogenetic analyses showing that PLENA and AGAMOUS are nonorthologous genes derived from a duplication in a common ancestor. Their respective orthologs, SHATTERPROOF in Arabidopsis and FARINELLI in Antirrhinum, have undergone independent subfunctionalization via changes in regulation and protein function. Surprisingly, the functional divergence between PLENA and FARINELLI, is morphologically manifest in both transgenic Antirrhinum and Arabidopsis. This provides a clear illustration of a random evolutionary trajectory for gene functions after a duplication event. Different members of a duplicated gene pair have retained the primary homeotic functions in different lineages, illustrating the role of chance in evolution. The differential ability of the Antirrhinum genes to promote male or female development provides a striking example of subfunctionalization at the protein level.

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Molecular and genetic interactions betweenSTYLOSAandGRAMINIFOLIAin the control ofAntirrhinumvegetative and reproductive development

et al. 2004

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GRAMINIFOLIA (GRAM), is supported by enhanced phenotypic defects in sty gram double mutants, for instance in the control of phyllotaxis, floral homeotic functions and organ polarity. Accordingly, the STY and GRAM protein and mRNA expression patterns overlap in emerging lateral organ primordia. STY is expressed in all meristems and later becomes confined to the adaxial domain and (pro)-vascular tissue. This pattern is similar to genes that promote adaxial identity, and, indeed, STY expression follows, although does not control, adaxial fate. We discuss the complex roles of STY and GRAM proteins in reproductive and vegetative development, performed in part in physical association but also independently.

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Genetic loci associated with field resistance to late blight in offspring of Solanum phureja and S.tuberosum grown under short-day conditions

Ghislain¹,

Trognitz²,

Herrera³

et al. 2001

Theor Appl Genet

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Field resistance to late blight -a fungal disease caused by Phytophthora infestans -has been genetically characterized by analyzing trait-marker association in a Solanum phureja (phu)×dihaploid Solanum tuberosum (dih-tbr) population. Trait data were developed at three locations over a 3-year period under natural infection pressure. RAPD (random amplified polymorphic DNA) and AFLP (amplified fragment length polymorphism) markers were used to develop anonymous genetic linkage groups subsequently anchored to potato chromosomes using mapped RFLP (restriction fragment length polymorphism), SSR (single sequence repeats) and AFLP markers. RFLP and SSR markers achieved the most-accurate anchoring. Two genetic maps were obtained, with 987.4 cM for phu and 773.7 cM for dih-tbr. Trait-marker association was revealed by single-marker and interval mapping analyses. Two important QTLs (quantitative trait loci) were detected on chromosomes VII and XII as a contribution from both parents, totalling up to 16% and 43%, respectively, of the phenotypic variation (PH). One additional QTL was detected on chromosome XI (up to 11% of the PH) as a contribution from the phu parent, and three others were detected on chromosome III (up to 13% of the PH), chromosome V (up to 11% of the PH) and chromosome VIII (up to 11% of the PH) as a contribution from the dih-tbr parent. Our results reveal new genetic loci of the potato genome that contribute to resistance to late blight. We postulate that some of these loci could be related to plant growth under short-day conditions.

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