The large, alpha-isoform of Rubisco activase confers redox regulation of the ATP/ADP response of the ATP hydrolysis and Rubisco activation activities of the multimeric activase holoenzyme complex. The alpha-isoform has a C-terminal extension that contains the redox-sensitive cysteine residues and is characterized by a high content of acidic residues. Cross-linking and site-directed mutagenesis studies of the C-terminal extension that have provided new insights into the mechanism of redox regulation are reviewed. Also reviewed are new details about the interaction between activase and Rubisco and the likely mechanism of 'activation' that resulted from mutagenesis in a 'Sensor 2' domain of activase that AAA(+) proteins often use for substrate recognition. Two activase residues in this domain were identified that are involved in Rubisco recognition. The results directly complement earlier studies that identified critical residues for activase recognition in the large subunit of Rubisco.
Temperature is one of the most important factors controlling growth, development, and reproduction in plants. The rate of photosynthesis declines at moderately high temperatures in plants and particularly in temperate species like Arabidopsis thaliana. This can be attributed to a reduced ability of Rubisco activase to achieve optimum activation of Rubisco, leading to reduced Rubisco activity. In order to overcome this problem, we transformed the Arabidopsis rca mutant with a more thermostable, chimeric activase where a Rubisco recognition domain in the more thermostable tobacco activase was replaced with that from Arabidopsis. Transgenic lines expressing this activase showed higher rates of photosynthesis than the wild type after a short exposure to higher temperatures and they also recovered better, when they were returned to the normal temperature. Moreover, under extended exposure to moderately elevated temperature, the transgenic lines had higher biomass and seed yield when compared with the wild type plants.
Rubisco activase is an AAA؉ protein, a superfamily with members that use a "Sensor 2" domain for substrate recognition. To determine whether the analogous domain of activase is involved in recognition of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco, EC 4.1.1.39), two chimeric activases were constructed, interchanging a Sensor 2-containing region between activases from spinach and tobacco. Spinach chimeric activase was a poor activator of both spinach and tobacco Rubisco. In contrast, tobacco chimeric activase activated spinach Rubisco far better than tobacco Rubisco, similar to spinach activase. A point mutation, K311D, in the Sensor 2 domain of the tobacco chimeric activase abolished its ability to better activate spinach Rubisco. The opposite mutation, D311K, in wild type tobacco activase produced an enzyme that activated both spinach and tobacco Rubisco, whereas a second mutation, D311K/L314V, shifted the activation preference toward spinach Rubisco. The involvement of these two residues in substrate selectivity was confirmed by introducing the analogous single and double mutations in cotton activase. The ability of the two tobacco activase mutants to activate wild type and mutant Chlamydomonas Rubiscos was also examined. Tobacco D311K activase readily activated wild type and P89R but not D94K Rubisco, whereas the tobacco L314V activase only activated D94K Rubisco. The tobacco activase double mutant D311K/L314V activated wild type Chlamydomonas Rubisco better than either the P89R or D94K Rubisco mutants, mimicking activation by spinach activase. The results identified a substrate recognition region in activase in which two residues may directly interact with two residues in Rubisco.Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) 1 activase is a chloroplast protein that activates and maintains Rubisco in an active state by facilitating removal of various sugar phosphates that either block substrate binding or prevent carbamoylation (1, 2). Plants lacking activase or having a very low level of activase cannot survive at atmospheric CO 2 levels (3, 4), and those expressing reduced levels exhibit reduced rates of photosynthesis and growth (5, 6). The activation process requires ATP hydrolysis (7), but this activity, as measured in vitro, appears to be related to self-association, which occurs even in the absence of Rubisco (8). The activase is subjected to redox regulation in Arabidopsis and probably other plant genera (9, 10). The proposed mechanism of action includes a binding step between activase and Rubisco, which is consistent with the kinetics of the activation process (11, 12).Although chemical cross-linking (13) and co-immunoprecipitation of Rubisco and activase have been reported (14, 15), most of the details of the binding process are still largely unknown. However, some insight into the process has been obtained by exploiting the peculiar specificity of Rubisco activase from plants in the family Solanaceae. Activase from plants in this family, which includes tobacco, tomato, pota...
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