Co-expression of plastid chaperonin genes and a synthetic plant Rubisco operon in Escherichia coli

It has been suggested that lack of specialized molecular chaperone function(s) in Escherichia coli may account for the fact that although E. coli cells transformed with plant Rubisco genes synthesize the Rubisco subunit polypeptides, the active enzyme fails to assemble. If so, co-expression of plant chaperone and Rubisco genes might permit plant Rubisco assembly in E. coli. Introduction of genes encoding plant chaperonin polypeptides has been shown to enhance the capacity of E. coli to assemble active cyanobacterial Rubisco. We now report that co-expression of plant Rubisco and chaperonin genes affected the solubility and stability of Rubisco large subunit polypeptides, however, neither the assembled oligomeric protein nor Rubisco enzyme activity was detected.     

Light-induced expression of ipt from Agrobacterium tumefaciens results in cytokinin accumulation and osmotic stress symptoms in transgenic tobacco

Cytokinins are plant growth regulators that induce shoot formation, inhibit senescence and root growth. Experiments with hydroponically grown tobacco plants, however, indicated that exogenously applied cytokinin led to the accumulation of proline and osmotin. These responses were also associated with environmental stress reactions, such as salt stress, in many plant species. To test whether increased endogenous cytokinin accumulation led to NaCl stress symptoms, the gene ipt from Agrobacterium tumefaciens, encoding isopentenyl transferase, was transformed into Nicotiana tabacum cv. SR-1 under the control of the light-inducible rbcS-3A promoter from pea. In high light (300 mol PPFD m^-2 s^-1), ipt mRNA was detected and zeatin/zeatin glucoside levels were 10-fold higher than in control plants or when transformants were grown in low light (30 mol PPFD m^-2 s^-1). High light treatment was accompanied by increased levels of proline and osmotin when compared to low light grown transformed and untransformed control plants. Elevated in planta cytokinin levels induced responses also stimulated by salt stress, suggesting either common or overlapping signaling pathways are initiated independently by cytokinin and NaCl, setting in motion gene expression normally elicited by developmental processes such as flowering or environmental stress.Abbreviations IPT isopentenyl, transferase - rbcS-3A gene encoding a small subunit protein (SSU) of Rubisco from Pisum sativum - Rubisco ribulose 1,5-bisphosphate carboxylase/oxygenase     

Expression of the isopentenyl transferase gene is regulated by auxin in transgenic tobacco tissues

The isopentenyl transferase gene (ipt) fromAgrobacterium tumefaciens was isolated and introduced, via a disarmed binary vector, into tobacco using theAgrobacterium tumefaciens-mediated gene transfer system. The expression of theipt gene was monitored by RNA hybridization, western blotting and cytokinin analysis. The addition of auxin to the media rapidly reduced the level of cytokinins in the transgenic tissues and this was associated with a reduction in IPT mRNA and protein levels. It is concluded that the hormone auxin can regulate expression of a gene involved in biosynthesis of the second hormone cytokinin. Although exogenous benzyladenine did not directly affectipt gene expression, it did antagonize the effect of auxin on levels of cytokinins and IPT mRNA and protein.     

Functional analysis of the Rubisco large subunit ÂN-methyltransferase promoter from tobacco and its regulation by light in soybean hairy roots

The ribulose-1,5-bisphosphate carboxylase/ oxygenase (Rubisco) large subunit (LS) ^ɛ N-methyltransferase (Rubisco LSMT) catalyzes post-translational methylation of the ɛ-amino group of lysine-14 in the LS of Rubisco. The entire nucleotide sequence for the tobacco (Nicotiana tabacum) Rubisco LSMT (rbcMT-T) gene including the putative promoter region was recently reported, and sequence analysis of the promoter region revealed seven GT-1 motifs. The ability of several truncated rbcMT-T promoter fragments to confer light responsiveness to reporter gene expression in transgenic soybean (Glycine max) hairy roots was examined. Chimeric constructs consisting of the rbcMT-T promoter fused to a bacterial β-glucuronidase (GUS) reporter gene and transferred to soybean via Agrobacterium rhizogenes were evaluated. The rbcMT-T promoter fragments conferred expression of the reporter gene in transgenic hairy roots, callus, and cell suspension cultures based on histochemical and fluorometric GUS analyses. The results suggest a quantitative role for the number of GT-1 motifs in determining differential expression between light and dark conditions. Received: 7 January 1998 / Revision received: 23 March 1998 / Accepted: 13 April 1998     

Chimaeras of the Rubisco Large Subunit from Wheat and Anacystis do not Assemble into Active Enzyme in E. coli

A new restriction site was engineered in the cloned gene codingfor the large subunit polypeptide of ribulose 1, 5-bisphosphatecarboxylase (Rubisco) of the cyanobacterium Anacystis nidulans.This change resulted in the mutation of a phenylalanine residueto an isoleucine residue in the encoded polypeptide but hadno effect on the assembly or biochemical properties of Rubiscocontaining the polypeptide. The mutation was in a loop regionlinking highly structured domains at the N and C termini ofthe complete large subunit. Using the new restriction site, and a corresponding EcoRl restrictionsite in the cloned gene for the native large subunit polypeptideof wheat Rubisco, chimaeric genes were made encoding the polypeptidewith either the 140 residues of the N-terminal part of the wheatlarge subunit fused to the 336 residues forming the C-terminalregion of the A. nidulans large subunit, or the alternativeof 136 residues comprising of the N-terminal chains of A. nidulanssubunit and the 338 residue chain at the C-terminus of the wheatlarge subunit polypeptide. The chimaeric proteins expressedin E. coli, together with the small subunit of the A. nidulansRubisco, formed an insoluble inactive aggregate mainly in inclusionbodies. The possible reasons for the failure to obtain activeholoenzyme are discussed. Key words: Rubisco, protein engineering, site-directed mutagenesis     

Synthesis of active Olisthodiscus luteus ribulose-1,5-bisphosphate carboxylase in Escherichia coli

The ribulose-1,5-bisphosphate carboxylase (Rubisco) large- and small-subunit genes are encoded on the chloroplast genome of the eukaryotic chromophytic alga Olisthodiscus luteus. Northern blot experiments indicate that both genes are co-transcribed into a single (>6 kb) mRNA molecule. Clones from the O. luteus rbc gene region were constructed with deleted 5 non-coding regions and placed under control of the lac promoter, resulting in the expression of high levels of O. luteus Rubisco large and small subunits in Escherichia coli. Sucrose gradient centrifugation of soluble extracts fractionated a minute amount of carboxylase activity that cosedimented with native hexadecameric O. luteus Rubisco. Most of the large subunit synthesized in E. coli appeared insoluble or formed an aggregate with the small subunit possessing an altered charge: mass ratio compared to the native holoenzyme. The presence in O. luteus of a polypeptide that has an identical molecular mass and cross reacts with antiserum generated against pea large-subunit binding protein may indicate that a protein of similar function is required for Rubisco assembly in O. luteus.     

Effects of cytokinin and senescence-inducing factors on expression of P ARR5 -GUS gene construct during leaf senescence in transgenic Arabidopsis thaliana plants

ARR5-gene expression was studied in the course of natural leaf senescence and detached leaf senescence in the dark using Arabidopsis thaliana plants transformed with the P _ARR5 -GUS gene construct. GUS-activity was measured as a marker of ARR5-gene expression. Chlorophyll and total protein amounts were also estimated to evaluate leaf senescence. Natural leaf senescence was accompanied by the progressive decline in the GUS-activity in leaves of the 2nd and 3rd nodes studied, and this shift of GUS-activity was more pronounced than the loss of chlorophyll content. The ability of the ARR5-gene promoter to respond to cytokinin was not eliminated during natural leaf senescence, as was demonstrated by a cytokinin-induced increase in GUS activity in leaves after their detachment and incubation on benzyladenine (BA, 5 × 10⁻⁶ M) in the dark. Leaf senescence in the dark was associated with the further decrease in the GUS-activity. The ARR5-gene promoter response to cytokinin was enhanced with the increase of the age of plants, taken as a source of leaves for cytokinin treatments. Hence, although the expression of the ARR5 gene reduces during natural and dark/detached leaf senescence, the ARR5-gene sensitivity to cytokinin was maintained in both cases and even increased with the leaf age. This data suggest that the ARR5 gene, which belongs to the type-A negative regulators of plant response to cytokinin, could be a feedback regulator able to prevent retardation by cytokinin of leaf senescence when it is important for plant life. Growth regulators either reduced ARR5 gene response to cytokinin during senescence of mature detached leaves in the dark (SA, meJA, ABA, SP) or increased it (IAA), thus modifying the resulting rate of its expression.     

Expression of Acidothermus cellulolyticus endoglucanase E1 in transgenic tobacco: biochemical characteristics and physiological effects

The expression of the Acidothermus cellulolyticus endoglucanase E1 gene in transgenic tobacco (Nicotiana tabacum) was examined in this study, where E1 coding sequence was transcribed under the control of a leaf specific Rubisco small subunit promoter (tomato RbcS-3C). Targeting the E1 protein to the chloroplast was established using a chloroplast transit peptide of Rubisco small subunit protein (tomato RbcS-2A) and confirmed by immunocytochemistry. The E1 produced in transgenic tobacco plants was found to be biologically active, and to accumulate in leaves at levels of up to 1.35% of total soluble protein. Optimum temperature and pH for E1 enzyme activity in leaf extracts were 81°C and 5.25, respectively. E1 activity remained constant on a gram fresh leaf weight basis, but dramatically increased on a total leaf soluble protein basis as leaves aged, or when leaf discs were dehydrated. E1 protein in old leaves, or after 5h dehydration, was partially degraded although E1 activity remained constant. Transgenic plants exhibited normal growth and developmental characteristics with photosynthetic rates similar to those of untransformed SR1 tobacco plants. Results from these biochemical and physiological analyses suggest that the chloroplast is a suitable cellular compartment for accumulation of the hydrolytic E1 enzyme.     

Cytokinin treatment of embryos inhibits the synthesis of chloroplast proteins in Norway spruce

A pulse treatment of Norway spruce (Picea abies (L.) Karst) embryos with the cytokinin N⁶-benzyladenine induces the formation of adventitious buds from subepidermal cells in the hypocotyl and cotyledons. In addition the treatment also inhibits elongation growth, a key process during germination. In this report we demonstrate that these effects on development of the plant are associated with a suppression of the accumulation of several major chloroplast proteins during germination. These proteins include the large subunit of ribulose bisphosphate/carboxylase oxygenase, two subunits of the chloroplast ATPase, protochlorophyllide reductase and a 23000-M_r component of photosystem II. For two nuclear-encoded proteins, the small subunit of ribulose bisphosphate carboxylase/oxygenase and the light-harvesting chlorophyll a/b-binding protein, a corresponding suppression of the increase in the steady-state amounts of mRNA is recorded. The suppression of chloroplast protein synthesis is consistant with the previously documented delay in greening that results from cytokinin treatment, but the effect is opposite to that found in other plants, where cytokinins promote the synthesis of chloroplast proteins, and stimulate chloroplast biogenesis. We believe that this difference is explained by the cytokinin primarily suppressing organ development, and a strict dependance of chloroplast biogenesis on the developmental state of the organs.Abbreviations Rubisco ribulose-1,5-bisphosphate carboxylase/oxygenase - CF1 coupling-factor 1 of chloroplast ATPase - LHCP light-harvesting chlorophyll a/b-binding protein - LSU large subunit of Rubisco - NADPH-protochlorophyllide oxidoreductase Pchlide reductase - SDS sodium dodecyl sulfate - SSU small subunit of Rubisco We thank K. Hutchison (Dept. of Biochemistry, University of Maine, Orono, Maine, USA) and P. Gustafsson (Dept. of Plant Physiology, University of Umeå, Sweden) for providing the Larix and Pinus clones, and M. Ryberg (Dept. of Plant Physiology, University of Göteborg, Sweden), R. Ölmüller (Botanisches Institut, Universität München, FRG) and W. Lockau (Institut für Botanik, Universität Regensburg, FRG), for the gift of antisera towards Pchlide reductase, RuBPCase and LHCP, and ATPase, respectively. Supported by the Swedish Council for Forestry and Agricultural Research and the Swedish Natural Sciences Research Council.     

Identification of STN7/STN8 kinase targets reveals connections between electron transport,metabolism and gene expression

The thylakoid‐associated kinases STN7 and STN8 are involved in short‐ and long‐term acclimation of photosynthetic electron transport to changing light conditions. Here we report the identification of STN7/STN8 in vivo targets that connect photosynthetic electron transport with metabolism and gene expression. Comparative phosphoproteomics with the stn7 and stn8 single and double mutants identified two proteases, one RNA‐binding protein, a ribosomal protein, the large subunit of Rubisco and a ferredoxin‐NADP reductase as targets for the thylakoid‐associated kinases. Phosphorylation of three of the above proteins can be partially complemented by STN8 in the stn7 single mutant, albeit at lower efficiency, while phosphorylation of the remaining three proteins strictly depends on STN7. The properties of the STN7‐dependent phosphorylation site are similar to those of phosphorylated light‐harvesting complex proteins entailing glycine or another small hydrophobic amino acid in the ?1 position. Our analysis uncovers the STN7/STN8 kinases as mediators between photosynthetic electron transport, its immediate downstream sinks and long‐term adaptation processes affecting metabolite accumulation and gene expression.     

A point mutation in the gene encoding the Rubisco large subunit interferes with holoenzyme assembly

Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco), a key enzyme of photosynthetic CO₂ fixation, is composed of 8 large and 8 small subunits. The Rubisco-deficient Nicotiana tabacum mutant Sp25 is able to synthesize the peptides for both subunits but does not contain any active holoenzyme. The phenotype is maternally inherited and thus caused by a mutation in the chloroplast genome, which also encodes the Rubisco large subunit. A comparison of the nucleotide sequences of the large subunit gene of the Sp25 mutant with that of the wild-type tobacco revealed a single nucleotide change in the Sp25 mutant. This resulted in an amino acid substitution at Gly-322, which was replaced by serine.     

A protein with an inactive pterin‐4a‐carbinolamine dehydratase domain is required for Rubisco biogenesis in plants

Ribulose‐1,5‐bisphosphate carboxylase/oxygenase (Rubisco) plays a critical role in sustaining life by catalysis of carbon fixation in the Calvin–Benson pathway. Incomplete knowledge of the assembly pathway of chloroplast Rubisco has hampered efforts to fully delineate the enzyme's properties, or seek improved catalytic characteristics via directed evolution. Here we report that a Mu transposon insertion in the Zea mays (maize) gene encoding a chloroplast dimerization co‐factor of hepatocyte nuclear factor 1 (DCoH)/pterin‐4α‐carbinolamine dehydratases (PCD)‐like protein is the causative mutation in a seedling‐lethal, Rubisco‐deficient mutant named Rubisco accumulation factor 2 (raf2‐1). In raf2 mutants newly synthesized Rubisco large subunit accumulates in a high‐molecular weight complex, the formation of which requires a specific chaperonin 60‐kDa isoform. Analogous observations had been made previously with maize mutants lacking the Rubisco biogenesis proteins RAF1 and BSD2. Chemical cross‐linking of maize leaves followed by immunoprecipitation with antibodies to RAF2, RAF1 or BSD2 demonstrated co‐immunoprecipitation of each with Rubisco small subunit, and to a lesser extent, co‐immunoprecipitation with Rubisco large subunit. We propose that RAF2, RAF1 and BSD2 form transient complexes with the Rubisco small subunit, which in turn assembles with the large subunit as it is released from chaperonins.     

Generation and suppression of microsomal ribonuclease activity after treatments with auxin and cytokinin

RNase activity was assayed in subcellular fractions of apical regions of Pisum sativum L. var. Alaska epicotyls after seedling decapitation and treatments with various growth regulators. High concentrations of applied indoleacetic acid caused a marked increase to occur in the RNase activity level associated with “heavy” microsomes, e.g., a 20-fold rise per unit RNA or protein in 3 days. This rise could be abolished by treating with the cytokinin benzyladenine along with indoleacetic acid. Nevertheless, indoleacetic acid and benzyladenine acted synergistically in their abilities to evoke swelling and net synthesis of RNA and protein. Polysomal profiles prepared after treatment with indoleacetic acid plus benzyladenine showed less degradation than profiles from any other treatment. It is concluded that auxin generates and cytokinin suppresses the activity of a particular membrane-bound RNase which can control turnover of the auxin-evoked polysomes required for growth in peas. Synergism between the two hormones in this system may be explained by the action of one to increase RNA synthesis and the other to decrease RNA destruction.     

Widespread positive selection in the photosynthetic Rubisco enzyme

Background  

Rubisco enzyme catalyzes the first step in net photosynthetic CO₂ assimilation and photorespiratory carbon oxidation and is responsible for almost all carbon fixation on Earth. The large subunit of Rubisco is encoded by the chloroplast rbcL gene, which is widely used for reconstruction of plant phylogenies due to its conservative nature. Plant systematicists have mainly used rbcL paying little attention to its function, and the question whether it evolves under Darwinian selection has received little attention. The purpose of our study was to evaluate how common is positive selection in Rubisco among the phototrophs and where in the Rubisco structure does positive selection occur.     

Antisense RNA inhibition of Rubisco activase expression

Ribulose bisphosphate carboxylase (Rubisco) activase catalyzes the activation of Rubisco in vivo. Activase antisense DNA mutants of tobacco have been generated to explore the control that activase exerts on the photosynthetic process. These mutants have up to 90% reductions in activase protein levels as a consequence of an inhibition of activase mRNA accumulation. It is shown that photosynthesis, measured as the rate of CO₂ exchange (CER), is modestly decreased in plants exposed to high irradiances. The decreases in CER in the transgenic plants are accompanied by corresponding decreases in Rubisco activation, indicating that activase has a direct effect on photosynthetic rates in the antisense plants by influencing the activation state of Rubisco. It is concluded that in high light conditions, control of photosynthesis is largely shared between Rubisco and activase. Plant growth is also impaired in mutant plants that have severe reductions in activase. The inhibition of activase in the antisense plants does not have an impact on the accumulation of Rubisco large subunit or small subunit mRNAs or proteins. This indicates that the concerted expression of the genes for activase (Rca) and Rubisco (rbcL and rbcS) in response to light, developmental factors and circadian controls is not due to feedback regulation of rbcL or rbcS by the amount of activase protein.