Edited by Marc C. E. Van Montagu, University of Ghent, Ghent, Belgium, and approved December 17, 1997 (received for review September 15, 1997) ABSTRACTOver 2,600 transgenic rice plants in nine strains were regenerated from >500 independently selected hygromycin-resistant calli after Agrobacterium-mediated transformation. The plants were transformed with fully modified (plant codon optimized) versions of two synthetic cryIA(b) and cryIA(c) coding sequences from Bacillus thuringiensis as well as the hph and gus genes, coding for hygromycin phosphotransferase and -glucuronidase, respectively. These sequences were placed under control of the maize ubiquitin promoter, the CaMV35S promoter, and the Brassica Bp10 gene promoter to achieve high and tissue-specific expression of the lepidopteran-specific ␦-endotoxins. The integration, expression, and inheritance of these genes were demonstrated in R 0 and R 1 generations by Southern, Northern, and Western analyses and by other techniques. Accumulation of high levels (up to 3% of soluble proteins) of CryIA(b) and CryIA(c) proteins was detected in R 0 plants. Bioassays with R 1 transgenic plants indicated that the transgenic plants were highly toxic to two major rice insect pests, striped stem borer (Chilo suppressalis) and yellow stem borer (Scirpophaga incertulas), with mortalities of 97-100% within 5 days after infestation, thus offering a potential for effective insect resistance in transgenic rice plants.Rice is one of the world's most important food crops, and intense efforts, including use of genetic engineering technologies, must be engaged to increase its yield if the impending global rice shortage is to be avoided (1). Engineering rice for pest resistance is a major challenge, one strategy being the introduction of Bacillus thuringiensis (Bt) crystal insecticidal protein (␦-endotoxin) genes (cry genes). These proteins (Bt toxins) are highly toxic to lepidopteran, dipteran, and coleopteran insects (2), among which are important pests of rice such as striped stem borer (SSB), yellow stem borer (YSB), and leaffolder (Cnaphalocrocis medinalis and Marasmia patnalis) that cause annual losses of an estimated 10 million tonnes (3).Rice plants containing cryIA(b) or cryIA(c) have been obtained by using protoplast (4) or particle bombardment methods (5-7). However, the numbers of plants obtained and levels of the toxin proteins in these studies were unfortunately still very low from a breeder's point of view. In contrast, Ͼ2,600 transgenic plants were produced with the modified cry genes in nine rice strains by using a modified Agrobacteriumbased rice transformation procedure (8). Herein we report that high levels of CryIA(b) and CryIA(c) were detected among these transgenic plants, indicating that many candidate transgenics in this large screen may be the result of optimal position effects. Insect feeding assays with R 1 plant tissues indicated that the transgenic plants were highly toxic to two major rice insects, SSB and YSB, with near 100% mortality within 5 days....
Ventricular muscle contains a low Km, cyclic AMP-specific form of phosphodiesterase (PDE III), which is believed to represent the site of action for several of new cardiotonic agents including imazodan (CI-914), amrinone, cilostamide, and enoximone. However, species differences in the inotropic response to these agents have raised questions about the relationship between PDE III inhibition and cardiotonic activity. The present study demonstrates that these differences can be accounted for by the presence of two subclasses of PDE III in ventricular muscle and variations in the intracellular localization of these two enzymes. For these experiments, PDE III was initially isolated from canine, guinea pig, and rat left ventricular muscle. The results demonstrate that canine left ventricular muscle contains two functional subclasses of PDE III: an imazodan-sensitive form, which is membrane bound, and an imazodan-insensitive form, which is soluble. Although only weakly inhibited by imazodan, this latter enzyme is potently inhibited by the selective PDE III inhibitors, Ro 20-1724 and rolipram. Guinea pig ventricular muscle also contains the imazodan-sensitive subclass of PDE III. Unlike canine left ventricle, however, thi enzyme is soluble in the guinea pig. No membrane-bound subclass of PDE III was observed in the guinea pig. Rat left ventricle possesses only the soluble form of PDE III, which apparently represents a mixture of the imazodan-sensitive and imazodan-insensitive subclasses of PDE III. Measurement of in vivo contractility in these three species showed that imazodan exerts a potent positive inotropic effect only in the dog, in which the imazodan-sensitive subclass of PDE III is membrane bound.(ABSTRACT TRUNCATED AT 250 WORDS)
1. A method is described for determining the ionization constants and reactivities of individual amino groups in proteins. The principle is that in the presence of a trace amount of radioactive label, the various reactive groups in a protein molecule will compete for the label and the amount incorporated into any one group will be determined by its nucleophilicity, pK and micro-environment. The relative amounts of label incorporated into various groups will be proportional to their second-order rate constants and by comparing these rate constants with those expected on the basis of a linear free-energy relationship obtained with a series of standard compounds, the micro-environment can be defined for a particular amino group. 2. The method consists of treating a protein and an internal standard with a limiting amount of radioactive reagent and then with an excess of unlabelled reagent to yield a chemically homogeneous but heterogeneously labelled compound. After appropriate enzymic digestion peptides containing each labelled group are isolated and their rates of reaction, relative to the internal standard, are determined from their specific radioactivities. The entire procedure is repeated at several pH values. 3. When the method was applied to the amino groups of porcine elastase by using tritiated acetic anhydride as the labelling reagent, the N-terminus was found to have pK(a) 9.7 and a much lower than normal reactivity. Lysine-87 and lysine-224 were found to have pK(a) 10.3 and normal reactivities. At pH values greater than 10.5 there are discontinuities in all the titration curves, indicating that the entire molecule is undergoing a structural reorganization.
Detailed photostability studies were carried out using purified delta-endotoxin crystals from Bacillus thuringiensis subspecies HD-1 and HD-73. The mechanism and time course of sunlight inactivation was investigated by: (a) monitoring the tryptophan damage in the intact crystals by Raman spectroscopy, (b) amino acid analysis and (c) biological assays using insects. The results demonstrate that, for purified HD-1 or HD-73 crystals, the 300-380 nm range of the solar spectrum is largely responsible for bringing about crystal damage and consequent loss of toxicity. Purified Bacillus thuringiensis crystals that were exposed to fermentation liquor after cell lysis were more quickly degraded by sunlight than were crystals from cells that were lysed in water. This effect is attributed to adsorption of chromophores by crystals exposed to the fermenter liquor and the subsequent ability of these chromophores to act as photosensitizers. The importance of a photosensitization mechanism in crystal degradation was further emphasized by irradiating Bacillus thuringiensis crystals in vacuo. The latter crystals were found to be less damaged (20% tryptophan loss after 24 h irradiation by the solar spectrum) compared with crystals from the same sample irradiated in air (60% (60% tryptophan loss). Other methods of decreasing exposure of the crystals to oxygen, e.g. by using glycerol as a humectant, were also found to be successful in controlling photodamage. The results concerning photodegradation support a photosensitization mechanism involving the presence of exogenous (and possibly endogenous) chromophores which create singlet oxygen species upon irradiation by light.
Trypsin is shown to generate an insecticidal toxin from the 130-kDa protoxin of Bacillus thuringiensis subsp. kurstaki HD-73 by an unusual proteolytic process. Seven specific cleavages are shown to occur in an ordered sequence starting at the C-terminus of the protoxin and proceeding toward the N-terminal region. At each step, C-terminal fragments of approximately 10 kDa are produced and rapidly proteolyzed to small peptides. The sequential proteolysis ends with a 67-kDa toxin which is resistant to further proteolysis. However, the toxin could be specifically split into two fragments by proteinases as it unfolded under denaturing conditions. Papain cleaved the toxin at glycine 327 to give a 34.5-kDa N-terminal fragment and a 32.3-kDa C-terminal fragment. Similar fragments could be generated by elastase and trypsin. The N-terminal fragment corresponds to the conserved N-terminal domain predicted from the gene-deduced sequence analysis of toxins from various subspecies of B. thuringiensis, and the C-terminal fragment is the predicted hypervariable sequence domain. A double-peaked transition was observed for the toxin by differential scanning calorimetry, consistent with two or more independent folding domains. It is concluded that the N-and C-terminal regions of the protoxin are two multidomain regions which give unique structural and biological properties to the molecule.Bacillus thuringiensis is an insect pathogen with an unusual but highly specific mode of action. During the sporulation cycle it lays down a parasporal protein crystal which is rendered toxic on ingestion by susceptible insect larvae. The major component of crystals toxic to lepidoptera is a protein (protoxin) with a molecular mass of approximately 130 kDa [l -31. Treatment with thiol reagents at basic pH solubilizes the protoxin by cleaving the disulfide bonds which stabilize the crystal. Incubation of the solubilized protoxin with proteolytic enzymes or insect gut juice produces a 58 -70-kDa proteinaseresistant toxin derived from the N-terminal portion of the molecule [4,5]. The toxin then binds to receptors in the midgut epithelium, causing cell lysis and eventual larval death [6 -81. The details of the lytic mechanism are not yet established but it appears that the toxin generates small pores or localized perturbations in the plasma membrane, causing disruption of homeostatic ion regulation [9].Large proteins are generally organized into distinct structural units referred to as domains or subdomains, but the criteria used for this classification is somewhat subjective. It is clear that the protoxin is divided into at least two major domains: the carboxyl half of the molecule which is readily attacked by proteinases, and the toxin derived from the Nterminal half which is proteinase-resistant. The toxins from
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