Abstract
The early-flowering habit of rapid-cycling accessions of Arabidopsis (Arabidopsis thaliana) is, in part, due to the genes of the autonomous floral-promotion pathway (AP). The AP promotes flowering by repressing expression of the floral inhibitor FLOWERING LOCUS C (FLC). AP mutants are therefore late flowering due to elevated levels of FLC, and this late-flowering phenotype is eliminated by loss-of-function mutations in FLC. To further investigate the role of the AP, we created a series of double mutants. In contrast to the phenotypes of single mutants, which are largely limited to delayed flowering, a subset of AP double mutants show a range of defects in growth and development. These phenotypes include reduced size, chlorophyll content, growth rate, and fertility. Unlike the effects of the AP on flowering time, these phenotypes are FLC independent. Recent work has also shown that two AP genes, FCA and FPA, are required for the repression and, in some cases, proper DNA methylation of two transposons. We show that similar effects are seen for all AP genes tested. Microarray analysis of gene expression in AP single and double mutants, however, suggests that the AP is not likely to play a broad role in the repression of gene expression through DNA methylation: very few of the genes that have been reported to be up-regulated in DNA methylation mutants are misexpressed in AP mutants. Together, these data indicate that the genes of the AP play important and sometimes functionally redundant roles in aspects of development in addition to flowering time.
Highlights
The early-flowering habit of rapid-cycling accessions of Arabidopsis (Arabidopsis thaliana) is, in part, due to the genes of the autonomous floral-promotion pathway (AP)
Double mutants were created between fpa and fca, fld, flk, fve, and ld in a Col background, which contains a strong allele of FLOWERING LOCUS C (FLC)
The visible phenotypes that have been reported for AP single mutants are primarily limited to delayed flowering
Summary
The early-flowering habit of rapid-cycling accessions of Arabidopsis (Arabidopsis thaliana) is, in part, due to the genes of the autonomous floral-promotion pathway (AP). Occurring winter annual types are late flowering, but the late-flowering phenotype can be eliminated by vernalization This late-flowering vernalization-responsive phenotype is created by the interaction of two genes: FLOWERING LOCUS C (FLC), a MADS domain-containing transcription factor that acts to repress flowering, and FRIGIDA (FRI), a gene of unknown biochemical function that activates the expression of FLC (Michaels and Amasino, 1999; Sheldon et al, 1999; Johanson et al, 2000). This loss of the vernalization requirement may have. Because rapid-cycling accessions, such as Columbia (Col), have lost FRI function, they contain low levels of FLC expression and do not require vernalization for early flowering. Plants containing either dominant alleles of FRI or recessive AP mutations behave as winter annuals
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