Molecular characterization of the brassinosteroid-deficient lkb mutant in pea.

The brassinosteriod-deficient lkb mutant of garden pea (Pisum sativum L.) is characterized by an erectoides phenotype (reduced internode length, thickened stems, epinastic leaves), which is rescued by application of exogenous brassinolide. We show that the LKB gene is the Arabidopsis DIMINUTO/DWARF-1 (DIM/DWF1) homologue of pea. The DIM/DWF1 homologue from lkb plants contains a mutation that may result in reduced enzyme function, thus resulting in the previously shown accumulation of 24-methylenecholesterol and a deficiency of its hydrogenated product, campesterol. This ultimately leads to a deficiency of the biologically active brassionolide. The mutation in the lkb sequence cosegregates with the lkb phenotype. Northern analyis of the LKB gene revealed that the gene is ubiquitously expressed around the plant and that there is no evidence for negative feedback regulation of the gene.

Interaction of phytochromes A and B in the control of de-etiolation and flowering in pea.

The interactions of phytochrome A (phyA) and phytochrome B (phyB) in the photocontrol of vegetative and reproductive development in pea have been investigated using null mutants for each phytochrome. White-light-grown phyA phyB double mutant plants show severely impaired de-etiolation both at the seedling stage and later in development, with a reduced rate of leaf production and swollen, twisted internodes, and enlarged cells in all stem tissues. PhyA and phyB act in a highly redundant manner to control de-etiolation under continuous, high-irradiance red light. The phyA phyB double mutant shows no significant residual phytochrome responses for either de-etiolation or shade-avoidance, but undergoes partial de-etiolation in blue light. PhyB is shown to inhibit flowering under both long and short photoperiods and this inhibition is required for expression of the promotive effect of phyA. PhyA is solely responsible for the promotion of flowering by night-breaks with white light, whereas phyB appears to play a major role in detection of light quality in end-of-day light treatments, night breaks and day extensions. Finally, the inhibitory effect of phyB is not graft-transmissible, suggesting that phyB acts in a different manner and after phyA in the control of flower induction.

Evidence that auxin promotes gibberellin A1 biosynthesis in pea.

In shoots of the garden pea, the bioactive gibberellin (GA1) is synthesised from GA20, and the enzyme which catalyses this step (a GA 3-oxidase -- PsGA3ox1) is encoded by Mendel's LE gene. It has been reported previously that decapitation of the shoot (excision of the apical bud) dramatically reduces the conversion of [3H]GA20 to [3H]GA1 in stems, and here we show that endogenous GA1 and PsGA3ox1 transcript levels are similarly reduced. We show also that these effects of decapitation are completely reversed by application of the auxin indole-3-acetic acid (IAA) to the 'stump' of decapitated plants. Gibberellin A20 is also converted to an inactive product, GA29, and this step is catalysed by a GA 2-oxidase, PsGA2ox1. In contrast to PsGA3ox1, PsGA2ox1 transcript levels were increased by decapitation and reduced by IAA application. Decapitation and IAA treatment did not markedly affect the level of GA1 precursors. It is suggested that in intact pea plants, auxin from the apical bud moves into the elongating internodes where it (directly or indirectly) maintains PsGA3ox1 transcript levels and, consequently, GA1 biosynthesis.

Characterization of the gene encoding the apoprotein of phytochrome B2 in tomato, and identification of molecular lesions in two mutant alleles.

The structure of the gene encoding the apoprotein of tomato phytochrome B2 (PHYB2) has been determined from genomic and cDNA sequences. The coding region is organized into four exons, like almost every other angiosperm phytochrome (phy). The deduced phyB2 apoprotein (PHYB2) consists of 1121 amino acids, with 82, 74 and 70% identity to tomato PHYB1, Arabidopsis PHYB, and Arabidopsis PHYD, respectively. In order to facilitate the identification of new mutants, we constructed a double mutant that is deficient in phyA and phyB1. When grown in white light, this mutant becomes only slightly taller than wild type and is similar in phenotype to the monogenic phyB1-deficient mutant. This double mutant has been used as the parent line for mutagenesis with gamma radiation. Several recessive mutants with long hypocotyls and reduced anthocyanin content were selected under white light and screened for mutations in PHYB2, PHYE and PHYF. Two of the triple-mutant lines, designated 55H and 70F, had elongated hypocotyls and fruit trusses, and pale immature fruits. Both belong to the same complementation group and both were found to have defects in PHYB2. Line 70F was found by Northern analysis to have a slightly larger PHYB2 transcript. Part or all of the intron between the second and third exons was found to be retained following RT-PCR of PHYB2 mRNA from line 70F. Three base substitutions were detected near the donor splice site for this intron, including a change from the consensus /GT to /GA at the 5' end of this intron. In every case, the C-terminal 164 amino acids of PHYB2 were replaced by 59 nonsense amino acids followed by a stop codon. Sequencing of PHYB2 from 55H revealed a single-nucleotide deletion near the end of the third exon, resulting in one incorrect codon followed immediately by a stop codon. The predicted mutant apoprotein in 55H is 90 residues shorter than wild-type PHYB2.

Molecular analysis of PHYA in wild-type and phytochrome A-deficient mutants of tomato.

Tomato (Lycopersicon esculentum Mill., recently redesignated Solanum lycopersicum L.), an agronomically important crop plant, has been adopted as a model species complementary to Arabidopsis in which to characterize the phytochrome family. Here we describe the cloning and molecular characterization of the gene encoding the apoprotein of phytochrome A in wild-type tomato and in the far-red-light-insensitive (fri1 and fri2) tomato mutants. The physical organization of this gene is similar to that of other angiosperm phytochromes with the four exons of the coding region interrupted by three introns. The pool of transcripts is heterogeneous due to multiple transcription start sites and to three modes of alternative splicing of the 5' leader. The leader in each alternative transcript carries multiple upstream open reading frames of considerable length. At the genomic level, both fri mutants share an identical base substitution which changes a consensus AG/ to TG/ at the 3' end of the intron between exons 1 and 2. This mutation leads to aberrant processing of the resultant pre-mRNA. While most mature transcripts retain the mutated intron, both cryptic splicing and exon skipping were also detected. Cryptic splicing occurred both upstream and downstream from the wild-type splice site. These observations are consistent with the hypothesis that exon definition in splicing of plant pre-mRNAs plays a secondary role to that of intron definition. Analysis of the frequency with which potentially functional phytochrome A apoproteins might be produced indicates that both fri1 and fri2 have less than 1% of the wild-type phytochrome A level.

Far-red light-insensitive, phytochrome A-deficient mutants of tomato.

We have selected two recessive mutants of tomato with slightly longer hypocotyls than the wild type, one under low fluence rate (3 mumol/m2/s) red light (R) and the other under low fluence rate blue light. These two mutants were shown to be allelic and further analysis revealed that hypocotyl growth was totally insensitive to far-red light (FR). We propose the gene symbol fri (far-red light insensitive) for this locus and have mapped it on chromosome 10. Immunochemically detectable phytochrome A polypeptide is essentially absent in the fri mutants as is the bulk spectrophotometrically detectable labile phytochrome pool in etiolated seedlings. A phytochrome B-like polypeptide is present in normal amounts and a small stable phytochrome pool can be readily detected by spectrophotometry in the fri mutants. Inhibition of hypocotyl growth by a R pulse given every 4 h is quantitatively similar in the fri mutants and wild type and the effect is to a large extent reversible if R pulses are followed immediately by a FR pulse. After 7 days in darkness, both fri mutants and the wild type become green on transfer to white light, but after 7 days in FR, the wild-type seedlings that have expanded their cotyledons lose their capacity to green in white light, while the fri mutants de-etiolate. Adult plants of the fri mutants show retarded growth and are prone to wilting, but exhibit a normal elongation response to FR given at the end of the daily photoperiod. The inhibition of seed germination by continuous FR exhibited by the wild type is normal in the fri mutants.(ABSTRACT TRUNCATED AT 250 WORDS)