Development of insect resistance in tomato plants expressing the δ-endotoxin gene ofBacillus thuringiensis subsp.tenebrionis

A crystal -endotoxin gene ofBacillus thuringiensis subsp.tenebrionis (B.t.t.) encoding a coleopteran insect-specific toxin was used to construct a chimeric gene which expressed the toxin in plant cells. Via anAgrobacterium tumefaciens binary vector system, the toxin gene was transferred into tomato cells. From leaf disks recombinant plants were regenerated. Hybridization experiments demonstrated that these plants synthesized toxin-specific mRNA of the expected size. Transgenic tomato plants with the chimericB.t.t. toxin gene contained a 74 kDa protein which cross-reacted with toxin antibodies. The expression caused a significant insecticidal activity of the transgenic tomato plants against Colorado potato beetle larvae.     

Apical and lateral shoot apex-specific expression is conferred by promoter of the seed storage protein β-phaseolin gene

A previous analysis with deletion mutants of the native -phaseolin gene demonstrated that removal of a negative element 5 upstream of–107 permitted phaseolin expression in stem cortex and secondary root (Burowet al., 1992). Here we employed the -glucuronidase (GUS) reporter gene to visualize, by histochemical staining, the cell type-specificity of phaseolin expression in stem and root, and to understand further the spatial control of the -phaseolin gene. The 782 bp 5 upstream promoter and its deletion mutants were fused to the GUS gene, and these chimaeric genes were used to transform tobacco. Histochemical staining for GUS activity demonstrated that phaseolin promoters truncated downstream of –227 conferred cell-type specific expression in internal/external phloem and protoxylem of mature stem. Surprisingly, GUS staining was prominent in both apical and lateral shoot apices of plants that contain the full-length –782 promoter and mutant promoters deleted up to –64. GUS expression was extended to all cell types of shoot tips, including epidermis, cortex, vasculature, procambium and pith. Expression in vasculature of petioles was limited to plants with promoters truncated to –106 and –64. The current results are in agreement with our previous findings with the native phaseolin gene: that the major positive element (–295/–228) is sufficient for seed-specific late-temporal expression of the phaseolin gene. We conclude that the 5 upstream sequence of the -phaseolin gene directs spatially- and temporally-controlled gene expression in developing seeds during the reproductive phase, but also confers expression in shoot apices during the vegetative phase of plant development.     

Cloning and sequencing of the hemA gene of Rhodobacter capsulatus and isolation of a δ-aminolevulinic acid-dependent mutant strain

Summary The Rhodobacter capsulatus hemA gene, coding for the enzyme -aminolevulinic acid synthase (ALAS), was isolated from a genome bank by hybridization with a hemT probe from Rhodobacter sphaeroides. Subcloning of the initial 3.9 kb HindIII fragment allowed the isolation of a 2.5 kb HindIII-BglII fragment which was able to complement the -aminolevulinic acid-requiring (ALA-requiring) Escherichia coli mutant SHSP19. DNA sequencing revealed an open reading frame coding for a protein with 401 amino acids which displayed similarity to the amino acid sequences of other known ALASs. However, no resemblance was seen to the HemA protein of E. coli K12. Based on the sequence data, an ALA-requiring mutant strain of R. capsulatus was constructed by site-directed insertion mutagenesis. Introduction of a plasmid, containing the hemA gene of R. capsulatus on the 3.9 kb HindIII fragment, restored ALA-independent growth of the mutant indicating that there is only one gene for ALA biosynthesis in R. capsulatus. Transfer of the R factor pRPS404 and hybridization analysis revealed that the ALAS gene is not located within the major photosynthetic gene cluster.Part of this research was presented at the Symposium on Molecular Biology of Membrane-Bound Complexes in Phototrophic Bacteria, Freiburg, FRG, 2–5 August 1989     

CD studies of peptides that mimic the four helicoidal sequences of the uteroglobin monomer

Summary Short peptides spanning the helicoidal sequences of the uteroglobin monomer (crystal forms P2₁ and C222₁) were synthesized and studied by circular dichroism spectroscopy. None of them showed any secondary structure in the absence of HFIP. However, most peptides achieved a helical conformation when this structuring agent was used, with the exception of the analogue corresponding to the helicoidal fragment 19–24 (helix II, crystal P2₁). These results indicate that other factors, such as interchain interactions, have to contribute to helix stabilization in the molecule. On the other hand, while peptides corresponding to N- and C-terminal fragments that contain the first and fourth helices of the monomer, respectively (1–14 and 48–70) achieved a -like structure when 10–15% of HFIP was used, this behaviour was not observed when TFE was used. Moreover, substitution of cysteine by -aminobutyric acid at position 3 increased both the helicity of fragment 1–14 and its ability to adopt a -like structure, but the opposite effect was observed for fragment 48–70 when -aminobutyric acid was introduced at position 69. These results indicate that this part of the protein might be sensitive to the chemical environment it is exposed to and that the two cysteine residues at positions 3 and 69 of the monomer could play a different role in the folding process.     

Interactions between esterified whey proteins (alpha-lactalbumin and beta-lactoglobulin) and DNA studied by differential spectroscopy

Spectroscopic study of interactions between esterified whey proteins and nucleic acids, at neutral pH, showed positive differential spectra over a range of wavelength between 210 and 340 nm. In contrast, native forms of whey proteins added to DNA did not produce any differential spectra. The positive difference in UV absorption was observed after addition of amounts of proteins as low as 138 molar ratio (MR) of protein/DNA, indicating high sensitivity of the applied method to detect interactions between basic proteins and DNA. UV-absorption differences increased with MR of added whey protein up to saturation. The saturation points were reached at relatively lower MR in the case of methylated forms of the esterified protein as compared to its ethylated form. Saturation of nucleic acid (2996 bp long) was achieved using 850 and 1100 MR of methylated -lactoglobulin and of methylated -lactalbumin, respectively. Saturation with ethylated forms of the proteins was reached at MR of 3160 and 2750. Lysozyme, a native basic protein, showed a behavior similar to what was observed in the case of methylated forms of the dairy proteins studied. However, in the case of lysozyme, saturation was achieved at relatively lower MR (700). Methylated -casein failed to give positive spectra at pH 7 in the presence of DNA. It interacted with DNA only when the pH of the medium was lowered to 6.5, below its pI. Generally, amounts of proteins needed to saturate nucleic acid were much higher than those needed to neutralize it only electrostatically, demonstrating the presence on DNA of protein-binding sites other than the negative charges on the sugar-phosphate DNA backbones. Addition of 0.1% SDS to the medium suppressed totally all spectral differences between 210–340 nm. The presence of 5 M urea in the medium reduced only the spectral differences between 210–340 nm, pointing to the role played by hydrophobic interactions. Peptic hydrolysates of esterified and native proteins or their cationic fractions (pH > 7) produced negative differential spectra when mixed with DNA. The negative differences in UV absorption spectra were the most important in the case of peptic hydrolysates of methylated derivatives of whey proteins.     

Synthesis of α-galacto-oligosaccharides by a cloned α-galactosidase from Bifidobacterium adolescentis

A genomic library of Bifidobacterium adolescentis was constructed in Escherichia coli and a gene encoding an -galactosidase was isolated. The identified open reading frame showed high similarity and identity with bacterial -galactosidases, which belong to Family 36 of the glycosyl hydrolases. For the purification of the enzyme from the medium a single chromatography step was sufficient. The yield of the recombinant enzyme was 100 times higher than from B. adolescentis itself. In addition to hydrolytic activity the -galactosidase showed transglycosylation activity and can be used for the production of -galacto-oligosaccharides.     

Correlation of physical maps and some genetic functions in the genomes of the kappa-theta phage family of Bacillus licheniformis

Summary Natural recombinant genomes between several, phenotypically distinct forms of phages and were isolated and characterized by DNA restriction fragment mapping and electron microscopic heteroduplex analysis. The phenotypes of the recombinants were correlated with the physical maps of the genomes, and several genetic functions were therfore defined and mapped. All genes necessary for the assembly of infectious virus particles map in a contiguous tract of DNA comprising about 20 kb, or nearly one third of the genome length. No DNA homology occurs within these domains of the two genomes, so that homologous recombination does not take place here and phenotypic mixing of the phages is eo ipso excluded. Other regions of heterology contain regulatory genes responsible for the lytic or temperate character of the phages, and for exclusion of phage by .     

Expression of Streptomyces genes encoding extracellular enzymes in Brevibacterium lactofermentum: secretion proceeds by removal of the same leader peptide as in Streptomyces lividans

The -amylase gene (amy) from Streptomyces griseus IMRU 3570 and the -galactosidase gene (lac) from S. lividans were subcloned into Brevibacterium lactofermentum or B. lactofermentum/Escherichia coli shuttle vectors. The amy gene was not expressed in B. lactofermentum from its own promoter but was efficiently expressed when the promoter of the kanamycin resistance gene (kan) was inserted upstream of the promoterless amylase gene. The lac gene from S. lividans was subcloned without its native promoter and was expressed when placed downstream of pBL1 promoters P₂ or P₃. The -amylase was secreted extracellularly by removal of the same 28-amino acid leader peptide as in S. lividans. The amy and lac genes provide useful markers for selection of transformants and will facilitate the study of protein secretion in B. lactofermentum. Correspondence to: J. F. Martín     

High-Activity Barley \bold\ralpha-Amylase by Directed Evolution

Barley -amylase isozyme 2 was cloned into and constitutively secreted by Saccharomyces cervisiae. The gene coding for the wild-type enzyme was subjected to directed evolution. Libraries of mutants were screened by halo formation on starch agar plates, followed by high-throughput liquid assay using dye-labeled starch as the substrate. The concentration of recombinant enzyme in the culture supernatant was determined by immunodetection, and used for the calculation of specific activity. After three rounds of directed evolution, one mutant (Mu322) showed 1000 times the total activity and 20 times the specific activity of the wild-type enzyme produced by the same yeast expression system. Comparison of the amino acid sequence of this mutant with the wild type revealed five substitutions: Q44H, R303K and F325Y in domain A, and T94A and R128Q in domain B. Two of these mutations, Q44H and R303K, result in amino acids highly conserved in cereal -amylases. R303K and F325Y are located in the raw starch-binding fragment of the enzyme molecule.