FPF1 transgene leads to altered flowering time and root development in rice.

AtFPF1 (FLOWERING PROMOTING FACTOR 1) is a gene that promotes flowering in Arabidopsis. An expression vector containing AtFPF1 driven by a Ubi-1 promoter was constructed. The gene was introduced into rice callus by Agrobacterium-mediated transformation and fertile plants were obtained. The presence of AtFPF1 in rice plants was confirmed by PCR, Southern and Northern blot analyses, as well as by beta-glucuronidase assay. The results showed that, as in Arabidopsis, AtFPF1 reduced flowering time in rice. Furthermore, introduction of AtFPF1 enhanced adventitious root formation but inhibited root growth in rice during the seedling stage. The results suggest that AtFPF1 promotes flowering time in both dicots and monocots, and plays a role in the initiation of adventitious roots in rice.

Two novel mitogen-activated protein signaling components, OsMEK1 and OsMAP1, are involved in a moderate low-temperature signaling pathway in rice.

Rice (Oryza sativa) anther development is easily damaged by moderately low temperatures above 12 degrees C. Subtractive screening of cDNA that accumulated in 12 degrees C-treated anthers identified a cDNA clone, OsMEK1, encoding a protein with features characteristic of a mitogen-activated protein (MAP) kinase kinase. The putative OsMEK1 protein shows 92% identity to the maize (Zea mays) MEK homolog, ZmMEK1. OsMEK1 transcript levels were induced in rice anthers by 12 degrees C treatment for 48 h. Similar OsMEK1 induction was observed in shoots and roots of seedlings that were treated at 12 degrees C for up to 24 h. It is interesting that no induction of OsMEK1 transcripts was observed in 4 degrees C-treated seedlings. In contrast, rice lip19, encoding a bZIP protein possibly involved in low temperature signal transduction, was not induced by 12 degrees C treatment but was induced by 4 degrees C treatment. Among the three MAP kinase homologs cloned, only OsMAP1 displayed similar 12 degrees C-specific induction pattern as OsMEK1. A yeast two-hybrid system revealed that OsMEK1 interacts with OsMAP1, but not with OsMAP2 and OsMAP3, suggesting that OsMEK1 and OsMAP1 probably function in the same signaling pathway. An in-gel assay of protein kinase activity revealed that a protein kinase (approximately 43 kD), which preferentially uses myelin basic protein as a substrate, was activated by 12 degrees C treatment but not by 4 degrees C treatment. Taken together, these results lead us to conclude that at least two signaling pathways for low temperature stress exist in rice, and that a MAP kinase pathway with OsMEK1 and OsMAP1 components is possibly involved in the signaling for the higher range low-temperature stress.

Changes in transcript levels of chloroplast psbA and psbD genes during water stress in wheat leaves.

In order to examine whether the decrease in gene expression of chloroplast DNA-encoded polypetides contributes to the inhibition of photosystem II (PSII) function during water stress, changes in transcript and template levels of chloroplast psbA and psbD genes (encoding the D1 and D2 reaction center proteins of PSII, respectively) were investigated in spring wheat leaves (Triticum aestivum L. cv. Longchun No. 10) using northern, Southern and dot blot analyses. The results of northern hybridization indicated that stressing wheat seedlings in polyethylene glycol (PEG) solutions with an osmotic potential of -0.5 MPa for 0, 24, 48 and 72 h, caused marked declines in the steady state levels of the psbA and psbD transcripts but did not alter their transcript processing patterns. RNA dot blot analysis further demonstrated that over the whole range of water stress investigated, the transcript levels of the two genes declined by 2- and 3-fold, respectively, relative to the same amount of total RNA. As total RNA decreased 3-fold during the process of stress, the transcript levels of psbA and psbD genes actually declined by 6- and 9-fold, respectively. These results suggest that water stress affects the expression of the psbA and psbD genes, possibly at the transcriptional level. Southern and DNA dot blot analyses consistently showed that water stress did not affect the template levels of either psbA or psbD genes, suggesting that the decreased abundance of psbA and psbD transcripts under water stress is not due to limited gene templates but likely a result of lowered gene transcriptional activity and/or changed mRNA stability.