Sequence of Lhcb3*1, a gene encoding a Photosystem II chlorophyll a/b-binding protein in Pisum

Catharanthus roseus genes regulated differentially by mollicute infections

A differential display of mRNAs was used to isolate periwinkle cDNAs differentially expressed following infection with one of three mollicutes: Spiroplasma citri, Candidatus Phytoplasma aurantifolia, and stolbur phytoplasma. Twenty-four differentially expressed cDNAs were characterized by Northern blots and sequence analysis. Eight of them had homologies with genes in databanks coding for proteins involved in photosynthesis, sugar transport, response to stress, or pathways of phytosterol synthesis. The regulation of these genes in periwinkle plants infected by additional phloem-restricted bacteria showed that they were not specific to a given mollicute, but correlations with particular symptoms could be established. Expression of transketolase was down regulated following infection with a pathogenic strain of S. citri. No down regulation was observed for the nonphytopathogenic mutant GMT553, which is deficient for fructose utilization.

Assessing modulation of stromal and thylakoid light-harvesting complex-II phosphatase activities with phosphopeptide substrates

The study of the light-harvesting complex II (LHC-II) phosphatase activity has been difficult due to the membrane association of its substrate. Thylakoid membranes labeled with [γ-(32)P]ATP were incubated with chymotrypsin, releasing phosphopeptides which served as labeled substrates for LHC-II phosphatase. Utilizing these phosphopeptides as substrates, protein phosphatase activities have been identified in both the thylakoid membrane and the stromal fraction. The thylakoid-bound phosphatase was liberated from the membrane with a sub-solubilizing concentration of Brij 35. The membrane and the stromal protein phosphatases were inhibited by NaF and EDTA, but not inhibited by microcystin-LR. The stromal phosphatase differed from the membrane phosphatase in pH optimum, in its lack of inhibition by molybdate ions, and by its response to magnesium and manganese ions. Using the soluble chymotryptic peptide substrate, the effect of light on pea thylakoid-bound LHC-II phosphatase activity was also assessed. Incubation of the thylakoid membranes in the light caused a 35% inhibition of LHC-II phosphatase activity. The inhibition was diminished by the addition of DCMU. Addition of 10 mM dithiothreitol stimulated the activity in darkness and obviated the inhibition when exposed to light. These studies suggest that positive or negative regulation of the LHC-II phosphatase activity is possible in vivo.

Sequence analysis of translationally controlled maternal mRNAs from Urechis caupo

Fertilization of Urechis caupo oocytes stimulates dramatic changes in the pattern of protein synthesis. This shift is brought about entirely through selective translation of the large pool of maternal mRNAs synthesized and stored during oogenesis. My laboratory has identified cDNA clones to more than 20 different Urechis maternal mRNAs. These have been used to determine whether the complementary mRNAs are translated in oocytes or embryos, and to analyze the polyadenylation status of the mRNAs at different stages. For 14 of the mRNAs, multiple, overlapping cDNA clones were isolated, and the complete sequence of the mRNA molecule was determined. Of these 14 mRNAs, half are from the subset that is translated in growing and full-grown oocytes, but not in embryos. These 7 mRNAs have poly(A) tails before fertilization. The other 7 are from the subset that is not translated at any time before fertilization, and has very short poly(A) tails in oocytes. After fertilization these mRNAs are recruited onto polysomes and extensively polyadenylated. The sequence data from the two classes of maternal mRNAs was compared in an attempt to identify consensus sequences that could regulate translation directly, or indirectly, by controlling polyadenylation or secondary structure formation. Two features of the sequences correlate very well with the translation and polyadenylation of the different mRNAs--the identity of the base immediately preceding the AUG start codon, and the presence of the sequences UUUUA and UUUUUA in the 3' untranslated region.