Jane Silverthorne

Light-dependent chloroplast development and expression of a light-harvesting chlorophyll a/b-binding protein gene in the gymnosperm Ginkgo biloba.

Unlike conifers, the gymnosperm Ginkgo biloba is dependent on light for chlorophyll (Chl) synthesis and initiation of chloroplast development. Dark-grown seedlings show complete etiolation, including no detectable Chl accumulation, no leaf expansion, and increased hypocotyl elongation. When dark-grown seedlings are placed in white light, Chl synthesis and leaf expansion are initiated, but unlike angiosperms, which initiate rapid photomorphogenesis, Ginkgo takes at least 1 week to change to a normal light-regulated pattern of growth. A cDNA clone (pLhcb*Gb1) encoding a Chl a/b-binding protein of light-harvesting complex II from Ginkgo mRNA has been used as a probe for the expression of this family of mRNAs. We have found that, in common with angiosperms but in marked contrast to pines, Lhcb mRNA is expressed in a highly light-dependent manner. In addition to being expressed in light-grown leaves, this sequence is also expressed in the green tissues of immature seeds. The Lhcb mRNA appears during greening in parallel with the onset of Chl synthesis. The complete sequence of pLhcb*Gb1 has been determined and the deduced amino acid sequence was found to be of type I based on comparison with signature sequences of angiosperm and gymnosperm sequences.

Organ-Specific Stability of Two Lemna rbcS mRNAs Is Determined Primarily in the Nuclear Compartment

It has previously been shown that the organ-specific expression of two members of the ribulose-1,5-bisphosphate carboxylase/oxygenase small subunit (rbcS) gene family is post-transcriptionally regulated in Lemna gibba. While both small subunit genes encoding SSU1 and SSU5B were transcribed at comparable levels in root and frond nuclei, SSU1 mRNA accumulated to high levels in both roots and fronds in contrast to SSU5B mRNA, which was of very low abundance in the roots compared with the fronds. In this study, we have used two approaches to pinpoint the step(s) at which SSU1 and SSU5B mRNAs are differentially accumulated in these organs. In the first approach, total nuclear steady state mRNA was isolated from roots and fronds, and the amount of each transcript was measured by RNase protection assays and compared with the transcription rates in isolated nuclei. In the second approach, cordycepin was used to inhibit mRNA synthesis in Lemna fronds or roots, and the rate of decay of each mRNA was measured by RNA gel blot analysis or RNase protection assays. Our findings indicate that the differential accumulation of SSU1 and SSU5B mRNAs in the fronds versus the roots is determined primarily in the nuclear compartment. In addition, SSU1 was found to have a longer half-life in total steady state mRNA than SSU5B had in both organs. This feature probably accounts for SSU1 being the predominantly expressed family member.