Jacqueline S. Knight

The N-terminal hydrophobic region of the mature phosphate translocator is sufficient for targeting to the chloroplast inner envelope membrane.

To locate the sequence required for directing the phosphate translocator to the chloroplast inner envelope membrane, a series of chimeric proteins constituting parts of the phosphate translocator and the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase, which is normally located in the stroma, has been produced. Reciprocal exchanges of the presequences and mature sequences of the phosphate translocator and the small subunit indicated that the phosphate translocator presequence contains stromal targeting information and that the mature protein is responsible for inner envelope membrane targeting. Chimeric proteins containing the N-terminal 46 amino acid residues of the phosphate translocator were directed to the inner envelope membrane. Subdivision of this region into its composite hydrophilic and hydrophobic regions showed that the hydrophobic region alone, which consists of amino acid residues 24 to 45, was able to direct the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase to the inner envelope membrane.

Expression of genes encoding the tobacco chloroplast phosphate translocator is not light-regulated and is repressed by sucrose

A cDNA encoding the complete precursor of the phosphate translocator of the chloroplast inner envelope membrane has been isolated from a tobacco leaf (Nicotiana tabacum cv. Samsun) λgt 11 library. The tobacco cDNA is 1546 by in length and encodes a precursor protein of 401 amino acid residues with a deduced molecular weight of 43705. A putative processing site between Ala-73 and Ala-74 of the precursor protein is suggested by comparison with the N-terminal sequences of the pea and spinach proteins. Removal of the transit peptide produces the mature protein of 328 amino acid residues with a molecular weight of 36038. Southern blot analysis suggests there is probably one copy of the phosphate translocator gene in the pea haploid genome and two copies in the tobacco haploid genome, one derived from each ancestral parental genome. Messenger RNAs essentially equivalent in size to the cDNAs (approx. 1.6 kb) were detected in extracts of all organs examined from tobacco and pea, including leaves, stems, sepals, petals, seed-pods, tendrils and roots. An immunochemically related protein of a similar size to the phosphate translocator was detected in the equivalent pea organs. The levels of both mRNA and protein in non-photosynthetic organs were lower than those in photosynthetic organs. Tobacco phosphate translocator mRNA was present at high levels in etiolated tissue and did not increase significantly after 24 h illumination. Germination and growth of tobacco seedlings in the presence of sucrose caused a 3.3-fold decrease in the level of the phoshate translocator mRNA.

Alteration of the Amount of the Chloroplast Phosphate Translocator in Transgenic Tobacco Affects the Distribution of Assimilate between Starch and Sugar

Tobacco plants (Nicotiana tabacum L.) transformed with sense and antisense constructs of a cDNA encoding the tobacco phosphate-triose phosphate-3-phosphoglycerate translocator (phosphate translocator) were shown to contain altered amounts of phosphate translocator mRNA and protein. Phosphate translocator activity in intact chloroplasts isolated from transformed plants showed a 15-fold variation, from 20% of the wild-type activity in antisense transformants to 300% of the wild-type activity in sense transformants. However, the maximal rates of photosynthesis and the rates of photosynthetic carbon assimilation in ambient CO2 showed no consistent differences between transformants. Starch content was decreased by 20% and total soluble sugars were increased by 20% in leaves of antisense transformants compared to sense transformants. The 40% decrease in the ratio of starch to total soluble sugars in antisense transformants relative to sense transformants indicates that distribution of assimilate between starch and sugar had been altered. However, the amount of sucrose in the leaves was unchanged. The changes in total soluble sugars were accounted for completely by changes in glucose and fructose, suggesting the existence of a homeostatic mechanism for maintaining sucrose concentrations in the leaves at the expense of glucose and fructose.

The regulation of component processes of photosynthesis in transgenic tobacco with decreased phosphoribulokinase activity

Tobacco plants (Nicotiana tabacum L.) transformed with an inverted cDNA encoding ribulose 5-phosphate kinase (phosphoribulokinase,PRK; EC 2.7.1.19) were employed to study the in vivo relationship between photosynthetic electron transport and the partitioning of electron transport products to major carbon metabolism sinks under conditions of elevated ATP concentrations and limited ribulose 1,5-bisphosphate (RuBP) regeneration. Simultaneous measurements of room temperature chlorophyll fluorescence and CO2 gas exchange were conducted on intact leaves. Under ambient CO2 concentrations and light intensities above those at which the plants were grown, transformants with only 5% of PRK activity showed ‘down-regulation” of PS II activity and electron transport in response to a decrease in net carbon assimilation when compared to wild-type. This was manifested as a decline in the efficiency of PS II electron transport (ΦPS II), an increase in dissipation of excess absorbed light in the antennae of PS II and a decline in: total linear electron transport (J1), electron transport dedicated to carbon assimilation (JA) and electron transport allocated to photorespiration (JL). The transformants showed no alteration in the Rubisco specificity factor measured in vitro and calculated in vivo but had a relatively smaller ratio of RuBP oxygenation to carboxylation rates (vo/vc), due to a higher CO2 concentration at the carboxylation site (Cc). The relationship between ΦPS II and ΦCO2was similar in transformants and wild-type under photorespiratory conditions demonstrating no change in the intrinsic relationship between PS II function and carbon assimilation, however, a novel result of this study is that this similar relationship occurred at different values of quantum flux, J1, JA, JL and vo/vc in the transformant. For both wild-type and transformants, an assessment was made of the possible presence of a third major sink for electron transport products, beside RuBP oxygenation and carboxylation, the data provided no evidence for such a sink.