Three 1-aminocyclopropane-1-carboxylate synthase genes regulated by primary and secondary pollination signals in orchid flowers.

The temporal and spatial expression patterns of three 1-aminocyclopropane-1-carboxylate (ACC) synthase genes were investigated in pollinated orchid (Phalaenopsis spp.) flowers. Pollination signals initiate a cascade of development events in multiple floral organs, including the induction of ethylene biosynthesis, which coordinates several postpollination developmental responses. The initiation and propagation of ethylene biosynthesis is regulated by the coordinated expression of three distinct ACC synthase genes in orchid flowers. One ACC synthase gene (Phal-ACS1) is regulated by ethylene and participates in amplification and interorgan transmission of the pollination signal, as we have previously described in a related orchid genus. Two additional ACC synthase genes (Phal-ACS2 and Phal-ACS3) are expressed primarily in the stigma and ovary of pollinated orchid flowers. Phal-ACS2 mRNA accumulated in the stigma within 1 h after pollination, whereas Phal-ACS1 mRNA was not detected until 6 h after pollination. Similar to the expression of Phal-ACS2, the Phal-ACS3 gene was expressed within 2 h after pollination in the ovary. Exogenous application of auxin, but not ACC, mimicked pollination by stimulating a rapid increase in ACC synthase activity in the stigma and ovary and inducing Phal-ACS2 and Phal-ACS3 mRNA accumulation in the stigma and ovary, respectively. These results provide the basis for an expanded model of interorgan regulation of three ACC synthase genes that respond to both primary (Phal-ACS2 and Phal-ACS3) and secondary (Phal-ACS1) pollination signals.

Abundance of an mRNA encoding a high mobility group DNA-binding protein is regulated by light and an endogenous rhythm.

A cDNA clone encoding an HMG1 protein from Pharbitis nil was characterized with regard to its sequence, genomic organization and regulation in response to photoperiodic treatments that control floral induction. The HMG1 cDNA contains an open reading frame of 432 nucleotides encoding a 144 amino acid protein of approximately 16 kDa. The predicted polypeptide has the characteristic conserved motifs of the HMG1 and HMG2 class of proteins including an N-terminal basic region, one of two HMG-box domains, and a polyacidic carboxy terminus. Within the HMG-box region, Pharbitis HMG1 deduced amino acid sequence shares 47%, 67% and 69% identity with its animal, maize, and soybean counterparts, respectively. Southern blot hybridization analysis suggests that HMG1 is a member of a multigene family. Analysis of mRNA abundance indicates that the HMG1 gene is expressed to higher levels in dark-grown tissue, such as roots, and at lower levels in light-grown tissue, such as cotyledons and stems. Following the transition to darkness, the levels of HMG1 mRNA in cotyledons were initially stable, however, after a lag time of 8 h or more, HMG1 mRNA increased in abundance to a peak level at 20 h. A second peak in mRNA levels was observed about 24 h later, indicating that the expression of the HMG1 gene is regulated by an endogenous circadian rhythm. Abundance of the HMG1 mRNA during a dark period was dramatically affected by brief light exposure (night break), a treatment which inhibits floral induction. These data indicate that the expression of HMG1 is regulated by both an endogenous rhythm and the light/dark cycle and are consistent with a role for HMG1 in maintaining patterns of circadian-regulated gene expression activated upon the transition from light to darkness.

Regional and cell-specific gene expression patterns during petal development.

We investigated gene expression patterns that occur during tobacco petal development. Two petal mRNA classes were identified that are present at elevated levels relative to other organs. One class is represented equally in the unpigmented tube and pigmented limb regions of the corolla. The other class accumulates preferentially within the limb region. Limb-specific mRNAs accumulate at different times during corolla development, peak in prevalence prior to flower opening, and are localized in either the epidermal cell layers or the mesophyll. The epidermal- and mesophyll-specific mRNAs change abruptly in concentration within a narrow zone of the limb/tube border. Preferential accumulation of at least one limb-specific mRNA occurs within the corolla upper region early in development prior to limb maturation and pigment accumulation. Limb-specific mRNAs also accumulate preferentially within the unpigmented corolla limb region of Nicotiana sylvestris, a diploid progenitor of tobacco. Runoff transcription studies and experiments with chimeric beta-glucuronidase genes showed that petal gene organ, cell, and region specificities are controlled primarily at the transcriptional level. We conclude that during corolla development transcriptional processes act coordinately on limb-specific genes to regulate their regional expression patterns, but act individually on these genes to define their cell specificities.