Abstract
Shoot apical meristems produce organs in a highly stereotypic pattern that involves auxin. Auxin is supposed to be actively transported from cell to cell by influx (AUXIN/LIKE AUXIN proteins) and efflux (PIN-FORMED proteins) membrane carriers. Current hypotheses propose that, at the meristem surface, PIN proteins create patterns of auxin gradients that, in turn, create patterns of gene expression and morphogenesis. These hypotheses are entirely based on work in Arabidopsis (Arabidopsis thaliana). To verify whether these models also apply to other species, we studied the behavior of PIN proteins during maize (Zea mays) development. We identified two novel putative orthologs of AtPIN1 in maize and analyzed their expression pattern during development. The expression studies were complemented by immunolocalization studies using an anti-AtPIN1 antibody. Interestingly, the maize proteins visualized by this antibody are almost exclusively localized in subepidermal meristematic layers. Both tassel and ear were characterized by a compact group of cells, just below the surface, carrying PIN. In contrast to or to complement what was shown in Arabidopsis, these results point to the importance of internally localized cells in the patterning process. We chose the barren inflorescence2 (bif2) maize mutant to study the role of auxin polar fluxes in inflorescence development. In severe alleles of bif2, the tassel and the ear present altered ZmPIN1a and ZmPIN1b protein expression and localization patterns. In particular, the compact groups of cells in the tassel and ear of the mutant were missing. We conclude that BIF2 is important for PIN organization and could play a role in the establishment of polar auxin fluxes in maize inflorescence, indirectly modulating the process of axillary meristem formation and development.
Highlights
Plant architecture is defined by the combination of external and internal cues, which determine the expression pattern of developmental genes
To identify maize PIN1-like genes belonging to the PIN family of putative auxin efflux carriers, we screened the National Center for Biotechnology Information (NCBI), The Institute for Genomic Research (TIGR), and Maize Genetics and Genomics Database (MaizeGDB) using the AtPIN1 (AT1G73590 for genomic DNA and AF089084 for cDNA) sequences as a query
Phylogenetic analysis shows that ZmPIN1a and ZmPIN1b fall into the same cluster together with the orthologous PIN1 proteins of rice, Arabidopsis, and wheat
Summary
Plant architecture is defined by the combination of external and internal cues, which determine the expression pattern of developmental genes. Polar auxin transport (PAT) is implicated in lateral organ initiation at the SAM in Arabidopsis (Arabidopsis thaliana), where it determines the position of flowers and leaves around the inflorescence stem (Reinhardt et al, 2000, 2003; Kuhlemeier and Reinhardt, 2001). This transport is supposed to be established and maintained by the members of two gene families: the PINFORMED (PIN) and AUXIN/LIKE AUXIN (AUX/ LAX) families. Once an organ primordium is initiated, the transport facilitator is present at the level of the internal prevascular tissues where it supposedly removes auxin from the meristem surface This general hypothesis was mainly established using Arabidopsis as a model system. They suggest a role for internal meristematic tissues in the patterning process, in contrast to what was proposed for Arabidopsis
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