Transgenic chickpea seeds expressing high levels of a bean α-amylase inhibitor

We describe a robust and reproducible Agrobacterium-mediated chickpea transformation method based on kanamycin selection, and its use to introduce the bean AI1 gene into a desi type of chickpea. Bean AI1 was specifically expressed in the seeds, accumulated up to 4.2% of seed protein and was processed to low molecular weight polypeptides as occurs in bean seeds. The transgenic protein was active as an inhibitor of porcine -amylase in vitro. Transgenic chickpeas containing -AI1 strongly inhibited the development of Callosobruchus maculatus and C. chinensis (Col. : Bruchidae) in insect bioassays.     

Identification of archaeon-producing hyperthermophilic α-amylase and characterization of the α-amylase

The extremely thermophilic anaerobic archaeon strain, HJ21, was isolated from a deep-sea hydrothermal vent, could produce hyperthermophilic alpha-amylase, and later was identified as Thermococcus from morphological, biochemical, and physiological characteristics and the 16S ribosomal RNA gene sequence. The extracellular thermostable alpha-amylase produced by strain HJ21 exhibited maximal activity at pH 5.0. The enzyme was stable in a broad pH range from pH 5.0 to 9.0. The optimal temperature of alpha-amylase was observed at 95 degrees C. The half-life of the enzyme was 5 h at 90 degrees C. Over 40% and 30% of the enzyme activity remained after incubation at 100 degrees C for 2 and 3 h, respectively. The enzyme did not require Ca(2+) for thermostability. This alpha-amylase gene was cloned, and its nucleotide sequence displayed an open reading frame of 1,374 bp, which encodes a protein of 457 amino acids. Analysis of the deduced amino acid sequence revealed that four homologous regions common in amylases were conserved in the HJ21 alpha-amylase. The molecular weight of the mature enzyme was calculated to be 51.4 kDa, which correlated well with the size of the purified enzyme as shown by the sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Inheritance of seed α-amylase inhibitor in the common bean and genetic relationship to arcelin

The inheritance of seed -amylase inhibitor in the common bean and the genetic relationships among the variants and six arcelin variants in the common bean were investigated by crossing between accessions containing different AI and arcelin variants. All seed proteins in parental, F₁ and F₂ seeds from the crosses were examined by Western-blot analysis. All F₁ seeds gave combined AI banding patterns from parents on the blotting membranes. The segregation of F₂ seeds for AI variants indicated that the polypeptides of AI variants were inherited as single co-dominant units. Moreover, AI and arcelin behaved as a single block in crosses, indicating a close linkage relationship between the genes controlling these proteins.     

Variation of seed α-amylase inhibitors in the common bean

Variation of seed -amylase inhibitors was investigated in 1 154 cultivated and 726 non-cultivated (wild and weedy) accessions of the common bean, Phaseolus vulgaris L. Four -amylase inhibitor types were recognized based on the inhibtion by seed extracts of the activities of porcine pancreatic -amylase and larval -amylase and larval -amylase of the Mexican bean weevil, Zabrotes subfasciatus Boheman. Of the 1 880 accessions examined most (1 734) were able to inhibit porcine pancreatic -amylase activity, but were inactive against the Z. subfasciatus larval -amylase; 41 inhibited only the larval -amylase activity, 52 inhibited the activities of the two -amylases, and 53 did not inhibit the activity of either of the -amylases. The four different inhibitor types were designated as AI-1, AI2, AI-3, and AI-0, respectively. These four inhibitor types were identified by the banding patterns of seed glycoproteins in the range of 14–20 kDa by using SDSpolyacrylamide gel electrophoresis. Additionally, four different banding patterns were recognized in accessions with AI-1, and were designated as AI-1a, 1b, 1c, and 1d. Two different patterns of the accessions lacking an -amylase inhibitory activity were identified and designated as AI-0a and AI-0b. The largest diversity for seed -amylase inhibitors was observed in non-cultivated accessions collected from Mexico where all eight inhibitor types were detected. The possible relationships between the variation of seed -amylase inhibitors and bruchid resistance are discussed.     

Purification and characterization of a thermostable α-amylase fromBacillus stearothermophilus

A soil isolate of Bacillus stearothermophilus was found to synthesize thermostable alpha-amylase. The enzyme was purified to homogeneity by ammonium sulfate fractionation and IECC on DEAE-cellulose column. The purified enzyme was considered to be a monomeric protein with a molar mass of 64 kDa, as determined by SDS-PAGE. The enzyme showed a wide range of pH tolerance and maximum activity at pH 7.0. The temperature tolerance was up to 100 degrees C with more than 90% catalytic activity; the maximum activity was observed at 50 degrees C. Divalent metal ions exhibited inhibitory effect on the enzyme activity. However, proteinase inhibitor did not react positively.     

Expression of α-amylase in cultured callus of french bean

α-Amylase (EC 3.2.1.1) expression was found in calli of French bean (Phaseolus vulgaris L. cv Goldstar). We examined enzyme activity in the calli to investigate influence of gibberellin and sugars on enzyme expression. After subculture of the calli, α-amylase activity decreased, and then increased at a stationary phase of callus growth. Exogenous application of gibberellin and an inhibitor of gibberellin synthesis, uniconazole, did not have any significant effects on the enzyme expression. Sugar starvation increased the activity, while addition of metabolizable sugars, such as sucrose, glucose and maltose, to the medium repressed expression. Addition of 6% mannitol, a non-metabolizable sugar, to the medium induced higher α-amylase expression as compared to addition of 3% mannitol. This result suggests that osmotic stress enhances α-amylase activity in the calli. Furthermore, high concentrations of agar in the medium increased α-amylase activity in the calli. It is probable that high concentrations of agar prevented incorporation of nutrient into the calli and induced the α-amylase activity in the calli.     

Characterization of α-amylase inhibitor from rice bean with inhibitory activity against midgut α-amylases from Spodoptera litura

The α-amylase inhibitor (α-AI) activity varied from 7.529 to 10.766 (IU/g) in 13 rice bean with different genotypes. BRS-2 exhibited the highest α-AI activity (55.3%). Rice bean α-AI was purified to homogeneity by 80% ammonium sulfate precipitation, dialysis, ion exchange chromatography on DEAE-Sepharose and gel filtration through Superdex-75. Its homogeneity was confirmed by SDS-PAGE under reducing conditions showing a single band protein of molecular weight 25 kDa. The inhibitor was purified to 75.9 fold with final yield of 28.0% with specific activity of 660.2 IU. Inhibition studies carried out at pH from 2.2 to 9.0 revealed pH optimum at pH 6.9 (69.3%). The maximum α-AI activity was found at 37°C (68.8 %) and the lowest was revealed at 100°C (37.0%). Optimum inhibitory activity was expressed during pre-incubation of enzyme with inhibitor at pH 6.9 and 37°C. Isoelectric focusing of purified inhibitor showed a single band near pH 4.7. The first 6 amino acids in the N-terminus were recorded as Ala-Ser-Ser-Arg-Phe-Cys (ASSRFC). The purified inhibitor inhibited the α-amylase from the larval midgut of Spodoptera litura up to 86.6%. The α-amylase inhibitors are important seed storage proteins because of their potentiality for exploitation in pest control and crop defense against insect infestation. Their expression at high levels can confer resistance in transgenic legumes, which could be exploited for crop improvement.     

Classification and characterization of the rice α-amylase multigene family

To establish the size and organization of the rice -amylase multigene family, we have isolated 30 -amylase clones from three independent genomic libraries. Partial characterization of these clones indicates that they fall into 5 hybridization groups containing a total of 10 genes. Two clones belonging to the Group 3 hybridization class have more than one gene per cloned fragment. The nucleotide sequence of one clone from Group 1, OSg2, was determined and compared to other known cereal -amylase sequences revealing that OSg2 is the genomic analog of the rice cDNA clone, pOS103. The rice -amylase genes in Group 1 are analogous to the -Amy1 genes in barley and wheat. OSg2 contains sequence motifs common to most actively transcribed genes in plants. Two consensus sequences, TAACA _G ^A A and TATCCAT, were found in the 5 flanking regions of -amylase genes of rice, barley and wheat. The former sequence may be specific to -amylase gene while the latter sequence may be related to a CATC box found in many plant genes. Another sequence called the pyrimidine box ( _T ^C CTTTT _T ^C ) was found in the -amylase genes as well as other genes regulated by gibberellic acid (GA). Comparisons based on amino acid sequence alignment revealed that the multigene families in rice, barley and wheat shared a common ancestor which contained three introns. Some of the descendants of the progenitor -amylase gene appear to have lost the middle intron while others maintain all three introns.     

Genomic and functional characterization of coleopteran insect-specific α-amylase inhibitor gene from Amaranthus species

The smallest 32 amino acid α-amylase inhibitor from Amaranthus hypochondriacus (AAI) is reported. The complete gene of pre-protein (AhAI) encoding a 26 amino acid (aa) signal peptide followed by the 43 aa region and the previously identified 32 aa peptide was cloned successfully. Three cysteine residues and one disulfide bond conserved within known α-amylase inhibitors were present in AhAI. Identical genomic and open reading frame was found to be present in close relatives of A. hypochondriacus namely Amaranthus paniculatus, Achyranthes aspera and Celosia argentea. Interestingly, the 3′UTR of AhAI varied in these species. The highest expression of AhAI was observed in A. hypochondriacus inflorescence; however, it was not detected in the seed. We hypothesized that the inhibitor expressed in leaves and inflorescence might be transported to the seeds. Sub-cellular localization studies clearly indicated the involvement of AhAI signal peptide in extracellular secretion. Full length rAhAI showed differential inhibition against α-amylases from human, insects, fungi and bacteria. Particularly, α-amylases from Helicoverpa armigera (Lepidoptera) were not inhibited by AhAI while Tribolium castaneum and Callosobruchus chinensis (Coleoptera) α-amylases were completely inhibited. Molecular docking of AhAI revealed tighter interactions with active site residues of T. castaneum α-amylase compared to C. chinensis α-amylase, which could be the rationale behind the disparity in their IC₅₀. Normal growth, development and adult emergence of C. chinensis were hampered after feeding on rAhAI. Altogether, the ability of AhAI to affect the growth of C. chinensis demonstrated its potential as an efficient bio-control agent, especially against stored grain pests.     

Concurrent occurrence of α-amylase inhibitor and stimulator in red kidney bean seed: physiological implications

It is hypothesized that since protein α-amylase inhibitor (α-AI) and stimulator might be present together in red kidney bean (Phaseolus vulgaris L.) seeds, their in vitro interactions might influence their detection and quantification. Assay of α-AI using extracts from the embryonic axes revealed an unexpected finding in that the extracts stimulated rather than inhibited α-amylase activity. The cotyledon extracts exhibited inhibitory or enhancement effect on α-amylase activity depending on whether prior to the α-amylase assay they had been boiled for 10 min or not. Phytohemagglutinin (PHA-L in particular) is implicated in the present study as a stimulator of α-amylase activity co-extracted with α-AI from red kidney bean cotyledons. The importance of these findings is discussed in relation to the possible widespread occurrence of protein α-amylase stimulator in seeds and other plant parts.     

Molecular cloning of the barley seed protein CMd: A variant member of the α-amylase/trypsin inhibitor family of cereals

The nucleotide and deduced amino-acid sequences of a cDNA clone encoding the barley seed protein CMd are described. The sequence is homologous with those of a family of inhibitors of α-amylase and trypsin, except for two short insertions. The longest of these (14 residues) is at the junction between the three proposed ancestral regions that comprise this family of proteins, and has limited identity with α-amylases of bacterial origin.     

Ostrich α-amylase: Purification and characterization of the pancreatic isoenzymes

• 1.1. Four ostrich pancreatic α-amylase isoenzymes were isolated by isoelectric focusing, following affinity chromatography on cyclohepta-amylose-Sepharose 4B.
• 2.2. Amino acid compositions of the four isoenzymes are very similar with only one charged amino acid (Arg) being significantly different.
• 3.3. The molecular weights, as determined by SDS-PAGE and amino acid composition, are nearly identical (52–53 kDa) for all four isoenzymes.
• 4.4. The four α-amylase isoenzymes appear to be kinetically distinct enzymes with a requirement for calcium.
• 5.5. Ostrich α-amylase isoenzymes appear to be non-glycosylated and contain one free thiol group.

     

SNP and haplotype identification of the wheat monomeric α-amylase inhibitor genes

Seventy-three gene sequences encoding monomeric α-amylase inhibitors were characterized from cultivated wheat “Chinese Spring”, group 6 nullisomic-tetrasomic lines of “Chinese Spring” and diploid putative progenitors of common wheat. The monomeric α-amylase inhibitors from the different sources shared very high homology (99.54%). The different α-amylase inhibitors, which were determined by the 24 single nucleotide polymorphisms (SNPs) of their gene sequences, were investigated. A total of 15 haplotypes were defined by sequence alignment, among which 9 haplotypes were found with only one single sequence sample. Haplotype H02 was found to be the main haplotype occurring in 83 WMAI sequence samples, followed by haplotype H11. The median-joining network for the 15 haplotypes of monomeric α-amylase inhibitor gene sequences from hexaploid wheats was star like, and at least two subclusters emerged. Furthermore evidence of homologous recombination was found between the haplotypes. The relationship between nucleotide substitutions and the amino acid changes in WMAI of hexaploid wheats was summarized. It was clear that only five polymorphic sites in the nucleotide sequence of WMAI resulted in amino acid variations, and that should be the reason for different structure and function of inhibitors. However, little evidence could be found that there were WMAI genes in the A genome of hexaploid wheat, whereas it could conclude from our results that the A genome diploid wheat had WMAI genes. The overall information on the monomeric α-amylase inhibitors from wheat and Aegilops strongly support the view that these inhibitors have evolved from a common ancestral gene through duplication and mutation. Ji-Rui Wang and Yu-Ming Wei are contributed equally to this paper.     

Purification and characterization of α-amylase fromAspergillus flavus

Aspergillus flavus produced approximately 50 U/mL of amylolytic activity when grown in liquid medium with raw low-grade tapioca starch as substrate. Electrophoretic analysis of the culture filtrate showed the presence of only one amylolytic enzyme, identified as an α-amylase as evidenced by (i) rapid loss of color in iodine-stained starch and (ii) production of a mixture of glucose, maltose, maltotriose and maltotetraose as starch digestion products. The enzyme was purified by ammonium sulfate precipitation and ion-exchange chromatography and was found to be homogeneous on sodium dodecyl sulfate— polyacrylamide gel electrophoresis. The purified enzyme had a molar mass of 52.5±2.5 kDa with an isoelectric point at pH 3.5. The enzyme was found to have maximum activity at pH 6.0 and was stable in a pH range from 5.0 to 8.5. The optimum temperature for the enzyme was 55°C and it was stable for 1 h up to 50°C. TheK _m andV for gelatinized tapioca starch were 0.5 g/L and 108.67 μmol reducing sugars per mg protein per min, respectively.     

Molecular basis for the specific binding of different α-amylase inhibitors from Phaseolus vulgaris seeds to the active site of α-amylase

In search of a possible mechanism of inhibition which might be responsible for the different specificities of the three isoforms of the bean (Phaseolus vulgaris) α-amylase inhibitor α-AI1, α-AI2 and α-AIL (EC 3.2.1.1), the two isoforms α-AI2 and α-AIL were modelled from the atomic co-ordinates of α-AI1 in the α-AI1/PPA complex and docking experiments were performed with pig pancreatic α-amylase (PPA) and the modelled amylase from Zabrotes subfasciatus (ZSA). The modelled α-AI2 penetrates without any steric hindrance in the substrate cleft of both enzymes but the possible hydrogen bonds between PPA and α-AI2 seem too few to maintain the stability of the complex. α-AIL, which differs from α-AI1 and α-AI2 by the absence of post-translational proteolytic cleavage and the occurrence of two additional loops of fifteen and six residues, creates steric clashes with PPA and ZSA that prevent its penetration into the substrate cleft of the enzyme. Docking experiments explain at the molecular level the specificity of α-amylase inhibitor isoforms towards enzymes of different origins. In addition, they explain why, according to its unprocessed and more bulky character, α-AIL was previously shown to be inactive on all α-amylases assayed. In fact, this last isoform is now considered as an evolutionary intermediate between phytohaemagglutinins, arcelins and α-amylase inhibitors.     

Assessment of the importance of α-amylase inhibitor-2 in bruchid resistance of wild common bean

Both α-amylase inhibitor-2 (αAI-2) and arcelin have been implicated in resistance of wild common bean (Phaseolus vulgaris L.) to the Mexican bean weevil (Zabrotes subfasciatus Boheman). Near isogenic lines (NILs) for arcelin 1–5 were generated by backcrossing wild common bean accessions with a cultivated variety. Whereas seeds of a wild accession (G12953) containing both αAI-2 and arcelin 4 were completely resistant to Z. subfasciatus, those of the corresponding NIL were susceptible to infestation, suggesting that the principal determinant of resistance was lost during backcrossing. Three independent lines of transgenic azuki bean [Vigna angularis (Willd.) Ohwi and Ohashi] expressing αAI-2 accumulated high levels of this protein in seeds. The expression of αAI-2 in these lines conferred protection against the azuki bean weevil (Callosobruchus chinensis L.), likely through inhibition of larval digestive α-amylase. However, although the seed content of αAI-2 in these transgenic lines was similar to that in a wild accession of common bean (G12953), it did not confer a level of resistance to Z. subfasciatus similar to that of the wild accession. These results suggest that αAI-2 alone does not provide a high level of resistance to Z. subfasciatus. However, αAI-2 is an effective insecticidal protein with a spectrum of activity distinct from that of αAI-1, and it may prove beneficial in genetic engineering of insect resistance in legumes.     

A tetrameric inhibitor of insect α-amylase from barley

A tetrameric inhibitor that is active against α-amylase from the larvae of the insect Tenebrio molitor, but inactive against the enzyme from human saliva and against the endogenous one, has been described in barley endosperm. The subunits of the inhibitor have been identified as the previously characterized proteins CMa, CMb and CMd, of which only CMa was inhibitory by itself.     

Purification and characterization of a truncatedBacillus subtilis α-amylase produced byEscherichia coli

ABacillus subtilis amylase gene was inserted into a plasmid which transferred toEscherichia coli. During cloning, a 3 region encoding 171 carboxyterminal amino acids was replaced by a nucleotide sequence that encoded 33 amino acid residues not present in the indigenous protein. The transformed cells produced substantial amylolytic activity. The active protein was purified to apparent homogeneity. Its molecular mass (48 kDa), as estimated in sodium dodecyl sulfate/polyacrylamide gel electrophoresis, was lower than the molecular mass values calculated from the derived amino acid sequences of theB. subtilis complete -amylase (57.7 kDa) and the truncated protein (54.1 kDa). This truncated enzyme form hydrolysed starch with aK _m of 3.845 mg/ml. Activity was optimal at pH 6.5 and 50°C, and the purified enzyme was stable at temperatures up to 50°C. While Hg²⁺, Fe³⁺ and Al³⁺ were effective in inhibiting the truncated enzyme Mn²⁺ and Co²⁺ considerably enhanced the activity.     

Effects of bean and wheat α-amylase inhibitors on α-amylase activity and growth of stored product insect pests

Insect α-amylase inhibiting and/or growth inhibiting activities of proteinaceous inhibitors from red kidney bean (Phaseolus vulgaris) and hard red winter wheat (Triticum aestivum) were examined. The bean inhibitor was most effectivein vitro against α-amylases from the red flour beetle (Tribolium castaneum) and the confused flour beetle (T. confusum), followed by those from the rice weevil (Sitophilus oryzae) and yellow mealworm (Tenebrio molitor). The insect enzymes were from two- to 50-fold more susceptible than human salivary α-amylase. When the inhibitors were added at a 1% level to a wheat flour plus germ diet, the growth of red flour beetle larvae was slowed relative to that of the control group of larvae, with the bean inhibitor being more effective than the wheat inhibitor. Development of both the red flour beetle and flat grain beetle (Cryptolestes pusillus) was delayed by 1% bean inhibitor, but development of the sawtoothed grain beetle (Oryzaephilus surinamensis) and lesser grain borer (Rhyzopertha dominica) was not affected by either the bean or wheat inhibitor at the 1% level. Rice weevil adults fed a diet containing 1% bean or wheat inhibitor exhibited more mortality than weevils fed the control diet. When the wheat amylase inhibitor was combined with a cysteine protease inhibitor, E-64, and fed to red flour beetle larvae, a reduction in the growth rate and an increase in the time required for adult eclosion occurred relative to larvae fed either of the inhibitors separately. The bean inhibitor was just as effective alone as when it was combined with the protease inhibitor. These results demonstrate that plant inhibitors of insect digestive enzymes act as growth inhibitors of insects and possibly as plant defense proteins, and open the way to the use of the genes of these inhibitors for genetically improving the resistance of cereals to storage pests. Cooperative investigation between the Agricultural Research Service, the University of California, San Diego, and the Kansas Agricultural Experiment Station (Contribution no. 94-416-J). Supported in part by a grant from the Ministry of Education and Science, Spain-Fulbright Program to J.J.P. Mention of a proprietary product does not constitute a recommendation or endorsement by the USDA. The USDA is an equal opportunity/affirmative action employer and all agency services are available without discrimination.