Cloning of an Arabidopsis thaliana gene encoding 5-enolpyruvylshikimate-3-phosphate synthase: sequence analysis and manipulation to obtain glyphosate-tolerant plants

Summary 5-enolpyruvylshikimate-3-phosphate synthase (EPSPs), the target of the herbicide glyphosate, catalyzes an essential step in the shikimate pathway common to aromatic amino acid biosynthesis. We have cloned an EPSP synthase gene from Arabidopsis thaliana by hybridization with a petunia cDNA probe. The Arabidopsis gene is highly homologous to the petunia gene within the mature enzyme but is only 23% homologous in the chloroplast transit peptide portion. The Arabidopsis gene contains seven introns in exactly the same positions as those in the petunia gene. The introns are, however, significantly smaller in the Arabidopsis gene. This reduction accounts for the significantly smaller size of the gene as compared to the petunia gene. We have fused the gene to the cauliflower mosaic virus 35 S promoter and reintroduced the chimeric gene into Arabidopsis. The resultant overproduction of EPSPs leads to glyphosate tolerance in transformed callus and plants.     

Insulin-stimulated tyrosine phosphorylation of a 43 kDa protein in rat liver membranes

The insulin receptor (IR) tyrosine kinase is essential for the regulation of different cellular functions by insulin. This may occur by a direct phosphorylation of membrane and/or cytoplasmic proteins by the IR tyrosine kinase. Hence it is important to identify putative physiological substrates for the IR tyrosine kinase. In this study we found that the glycoprotein fraction from rat liver membranes contain a 43 kDa protein (pp43) which, like the -subunit of IR, is phosphorylated in an insulin-dependent manner. A 25-fold enhancement of ³²P incorporation into pp43 by insulin was found under optimal conditions. Half-maximal phosphorylation of pp43 and the -subunit of IR were attained at 66 nM and 60 nM insulin, respectively. Mn²⁺ (K_a = 1.0 mM) was much better than Mg²⁺ (K_a = 6.3 mM) in supporting pp43 phosphorylation. Insulin-stimulated phosphorylation of pp43 (t_1/2 = 3.6 min) proceeded at a much slower rate compared to that of the -subunit of IR (t_1/2 = 1.2 min). Phosphoamino acid analysis of pp43 revealed that both tyrosine and serine are phosphorylated in the ratio 4 : 1. Tyrosine, but not serine, phosphorylation was increased 12-fold by insulin. Phosphorylation of pp43 occurred on 4 major tryptic peptides. Comparison to the tryptic phosphopeptides from IR -subunit suggest that pp43 was not derived from IR -subunit by proteolysis. Our results suggest that pp43 may be an endogenous substrate for the IR tyrosine kinase.     

The GTP-binding regulatory proteins of neuroblastoma x glioma, NG108-15, and glioma, C6, cells. Immunochemical evidence of a pertussis toxin substrate that is neither Ni nor No

Amounts of the guanine nucleotide binding regulatory proteins which are also pertussis toxin substrates (such as Ni and No) were measured in rat glioma, C6BU-1, cells and in neuroblastoma X glioma, NG108-15, hybrid cells. Measurements were performed both by quantitating pertussis toxin catalyzed ADP-ribosylation and by quantitative immunoblotting with affinity purified antibodies specific for Ni or No. The amounts of pertussis toxin substrate in C6 and NG108-15 cells are 7.5 and 0.6 pmol/mg membrane protein, respectively. These levels are minimum values and higher estimates of the total amounts of N proteins in the two cells are obtained by quantitative immunoblot analysis of the beta-subunit common to all N proteins. Immunoblots with specific antibodies show that NG108-15 cells contain 3.8 pmol/mg of No and detectable but small (less than 0.1 pmol/mg) amounts of Ni. In contrast, C6 cell membranes contain no detectable No and only 0.14 pmol/mg Ni. Thus, C6 cells contain large amounts of a pertussis toxin substrate which is neither Ni nor No.     

Alterations of Endogenous Cytokinins in Transgenic Plants Using a Chimeric Isopentenyl Transferase Gene

Cytokinins, a class of phytohormones, appear to play an important role in the processes of plant development. We genetically engineered the Agrobacterium tumefaciens isopentenyl transferase gene, placing it under control of a heat-inducible promoter (maize hsp70). The chimeric hsp70 isopentenyl transferase gene was transferred to tobacco and Arabidopsis plants. Heat induction of transgenic plants caused the isopentenyl transferase mRNA to accumulate and increased the level of zeatin 52-fold, zeatin riboside 23-fold, and zeatin riboside 5[prime]-monophosphate twofold. At the control temperature zeatin riboside and zeatin riboside 5[prime]-monophosphate in transgenic plants accumulated to levels 3 and 7 times, respectively, over levels in wild-type plants. This uninduced cytokinin increase affected various aspects of development. In tobacco, these effects included release of axillary buds, reduced stem and leaf area, and an underdeveloped root system. In Arabidopsis, reduction of root growth was also found. However, neither tobacco nor Arabidopsis transgenic plants showed any differences relative to wild-type plants in time of flowering. Unexpectedly, heat induction of cytokinins in transgenic plants produced no changes beyond those seen in the uninduced state. The lack of effect from heat-induced increases could be a result of the transient increases in cytokinin levels, direct or indirect induction of negating factor(s), or lack of a corresponding level of competent cellular factors. Overall, the effects of the increased levels of endogenous cytokinins in non-heat-shocked transgenic plants seemed to be confined to aspects of growth rather than differentiation. Since no alterations in the programmed differentiation pattern were found with increased cytokinin levels, this process may be controlled by components other than absolute cytokinin levels.     

CBP-18, a Ca2+-Binding Protein in Rat Brain: Tissue Distribution and Localization

Abstract: The distribution of a novel calcium-binding protein with a molecular mass of 18 kDa (CBP-18) in the rat brain was studied by means of biochemical methods and immunohistochemistry on cryostat-sectioned tissue and compared with staining patterns of parvalbumin on adjacent sections. The biochemical analysis revealed high levels of CPB-18 in cortex and cerebellum, low levels in the lungs, and undetectable levels in all other tissues tested. Immunohistochemically, the polyclonal rabbit-derived antibody for CPB-18 showed selective affinity with periglomerular cells and dendrites in the olfactory bulb. Distinct immunostaining of scattered cells and their proximal dendrites was found in the anterior olfactory nuclei and in the perirhinal and entorhinal cortex. Strong staining of neuropil with recognizable but diffusely outlined cells was observed in the retrosplenial cortex, central amygdala, hippocampal rudiment, septum, area preoptica, hypothalamus, colliculus superior, and parabrachial nuclei. The cerebellum showed strong neuropil staining of both the molecular and the granule cell layer. Less intense neuropil staining and a few scattered cells were found in the neocortex, the remaining basal forebrain, and in the entire brainstem. Immunoreactivity was barely detectable or missing in the striatum, the hippocampus, the thalamus, and in the colliculus inferior. Thus, CPB-18 shows a unique staining pattern in the CNS, different from all other Ca²⁺-binding proteins studied so far.     

Characterization of a high-affinity monoclonal antibody to calcineurin whose epitope defines a new structural domain of calcineurin A

Monoclonal antibodies have been raised against native calcineurin using conventional in vivo immunization and hybridoma procedures. The relatively high affinity of nonimmune IgG for the two subunits of calcineurin resulted in large nonspecific binding values for immunoassays of native, dissociated and denatured calcineurin, which complicated the antibody screening. Monoclonal aCn5, a high-affinity IgG1 that exhibits specific binding, was characterized. Other calmodulin-binding proteins tested were not recognized by aCn5. Simple binding properties were exhibited in solid-phase experiments, Kd = 26 (+/- 4) pM, but the stoichiometry was low. The loss of immunoreactivity after denaturation of calcineurin indicated that the aCn5 epitope is of the assembled topographic, not segmental, type. The epitope was located to the A subunit and affinity was unaffected by the presence of calcineurin B. The epitope remained intact after proteolytic removal of the amino-terminal 20 residues of calcineurin A essential for phosphatase activity, and the carboxyl-terminal inhibitory and calmodulin-binding domains. The calmodulin-binding peptide derived from calcineurin, cA8, was not recognized by aCn5. Addition of Ca2+, Mn2+, Ni2+, chelators or dithiothreitol did not influence the affinity of aCn5 for the holoenzyme. Phosphatase activity of calcineurin, in the presence and absence of calmodulin and after removal of the inhibitory domain, was little affected by aCn5. Thus, the aCn5 epitope defines a previously unidentified structural domain of calcineurin A located in a region of the proteolytically resistant core that is topologically distinct from the catalytic, inhibitory, calmodulin-binding and calcineurin-B-binding domains, and not functionally connected with calcineurin B or the putative metal-binding domain(s).