Arg-27, Arg-127 and Arg-155 in the beta-trefoil protein barley alpha-amylase/subtilisin inhibitor are interface residues in the complex with barley alpha-amylase 2

A glycoprotein α-amylase inhibitor from Withania somnifera differentially inhibits various α-amylases and affects the growth and development of Tribolium castaneum

BACKGROUND

Identification and characterisation of plant defensive molecules enrich our resources to design crop protection strategies. In particular, plant-derived proteinaceous inhibitor(s) of insect digestive enzymes appear to be a safe, sustainable and attractive option.

RESULTS

A glycoprotein having non-competitive α-amylase inhibitory activity with a molecular weight of 8.3 kDa was isolated and purified from seeds of Withania somnifera α-amylase inhibitor (WSAI). Its mass spectrometry analysis revealed 59% sequence coverage with Wrightide II-type α-amylase inhibitor from Wrightia religiosa. A dose-dependent inhibition of α-amylases from Aspergillus oryzae, Bacillus subtilis, Helicoverpa armigera and Tribolium castaneum was recorded. Interestingly, WSAI did not inhibit human salivary α-amylase significantly. When adults of T. castaneum were fed with WSAI (1.6 mg g^-1 ), decrease in consumption, growth and efficiency of conversion of ingested food was evident, along with over fourfold increases in feeding deterrence index. A decline in larval residual α-amylase activity after feeding of WSAI resulted in a reduction in longevity of T. castaneum.

CONCLUSION

The study reflects the significance of WSAI in affecting the overall growth and development of T. castaneum. Pre- and post-harvest pest resistive capability makes WSAI a potential candidate for insect pest management. Further, the effectiveness of this inhibitor could be explored either in formulations or through a transgenic approach. © 2016 Society of Chemical Industry.

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.

High-level expression of the native barley alpha-amylase/subtilisin inhibitor in Pichia pastoris

An expression system for high-level expression of the native Hordeum vulgare alpha-amylase/subtilisin inhibitor (BASI) has been developed in Pichia pastoris, using the methanol inducible alcohol oxidase 1 (AOX1) promoter. To optimize expression, two codon-optimized coding regions have been designed and expressed alongside the wild-type coding region. To ensure secretion of the native mature protein, a truncated version of the alpha mating factor secretion signal from Saccharomyces cerevisiae was used. In order to be able to compare expression levels from different clones, single insertion transformants generated by gene replacement of the AOX1 gene was selected by PCR screening. Following methanol induction, expression levels reached 125 mgL(-1) from the wild-type coding region while expression from the two codon-optimized variants reached 65 and 125 mgL(-1), respectively. The protein was purified and characterized by Edman degradation, liquid chromatography mass spectrometry and insoluble blue starch assay, and was shown to possess the same characteristics as wild-type protein purified from barley grains.

XIP-I, a xylanase inhibitor protein from wheat: a novel protein function

Endo-(1,4)-beta-xylanases of plant and fungal origin play an important role in the degradation of arabinoxylans. Two distinct classes of proteinaceous endoxylanase inhibitors, the Triticum aestivum xylanase inhibitor (TAXI) and the xylanase inhibitor protein (XIP), have been identified in cereals. Engineering of proteins in conjunction with enzyme kinetics, thermodynamic, real-time interaction, and X-ray crystallographic studies has provided knowledge on the mechanism of inhibition of XIP-I towards endoxylanases. XIP-I is a 30 kDa protein which belongs to glycoside hydrolase family 18, and folds as a typical (beta/alpha)8 barrel. Although the inhibitor shows highest homology with plant chitinases, XIP-I does not hydrolyse chitin; probably due to structural differences in the XIP-I binding cleft. The inhibitor is specific for fungal xylanases from glycoside hydrolases families 10 and 11, but does not inhibit bacterial enzymes. The inhibition is competitive and, depending on the xylanase, the Ki value can be as low as 3.4 nM. Site-directed mutagenesis of a xylanase from Aspergillus niger suggested that the XIP-I binding site was the conserved hairpin loop "thumb" region of family 11 xylanases. Furthermore, XIP-I shows the ability to inhibit barley alpha-amylases of glycoside hydrolase family 13, providing the first example of a protein able to inhibit members of different glycoside hydrolase families (10, 11, and 13), and additionally a novel function for a protein of glycoside hydrolase family 18.

Cross-inhibitory activity of cereal protein inhibitors against alpha-amylases and xylanases

The purification and characterisation of a xylanase inhibitor (XIP-I) from wheat was reported previously. In our current work, XIP-I is also demonstrated to have the capacity to inhibit the two barley alpha-amylase isozymes (AMY1 and AMY2). XIP-I completely inhibited the activity of AMY1 and AMY2 towards insoluble Blue Starch and a soluble hepta-oligosaccharide derivative. A ternary complex was formed between insoluble starch, a catalytically inactive mutant of AMY1 (D180A), and XIP-I, suggesting that the substrate-XIP-I interaction is necessary for inhibition of barley alpha-amylases. K(i) values for alpha-amylase inhibition, however, could not be calculated due to the nonlinear nature of the inhibition pattern. Furthermore, surface plasmon resonance and gel electrophoresis did not indicate interaction between XIP-I and the alpha-amylases. The inhibition was abolished by CaCl(2), indicating that the driving force for the interaction is different from that of complexation between the barley alpha-amylase/subtilisin inhibitor (BASI) and AMY2. This is the first report of a proteinaceous inhibitor of AMY1. BASI, in addition, was demonstrated to partially inhibit the endo-1,4-beta-D-xylanase from Aspergillus niger (XylA) of glycoside hydrolase family 11. Taken together, the data demonstrate for the first time the dual target enzyme specificity of BASI and XIP-I inhibitors for xylanase and alpha-amylase.

Purification and characterization of the beta-trefoil fold protein barley alpha-amylase/subtilisin inhibitor overexpressed in Escherichia coli

Barley alpha-amylase/subtilisin inhibitor (BASI) is a beta-trefoil fold protein related to soybean trypsin inhibitor (Kunitz) and inhibits barley alpha-amylase isozyme 2 (AMY2), which is de novo synthesized in the seed during germination. Recombinant BASI was produced in Escherichia coli in an untagged form (untagged rBASI), in two His(6)-tag forms (His(6)-rBASI and His(6)-Xa-rBASI), and in an intein-CBD-tagged form (rBASI (intein)). The yields per liter culture after purification were (i) 25 mgl(-1) His(6)-rBASI; (ii) 6 mgl(-1) rBASI purified after cleavage of His(6)-Xa-rBASI by Factor Xa; (iii) 3 mgl(-1) untagged rBASI; and (iv) 0.2 mgl(-1) rBASI after a chitin-column and autohydrolysis of the rBASI-intein-CBD. In Pichia pastoris, rBASI was secreted at 0.1 mgl(-1). The recombinant BASI forms and natural seed BASI (sBASI) all had an identical isoelectric point of 7.2 and a mass of 19,879 Da, as determined by mass spectrometry. The fold of rBASI from the different preparations was confirmed by circular dichroism spectroscopy and rBASI (intein), His(6)-rBASI, and sBASI inhibited AMY2 catalyzed starch hydrolysis with K(i) of 0.10, 0.06, and 0.09 nM, respectively. Surface plasmon resonance analysis of the formation of AMY2/rBASI (intein) gave k(on)=1.3x10(5)M(-1)s(-1), k(off)=1.4x10(-4)s(-1), and K(D)=1.1 nM, and of the savinase-His(6)-rBASI complex k(on)=21.0x10(4)M(-1)s(-1), k(off)=53.0x10(-4)s(-1), and K(D)=25.0 nM, in agreement with sBASI values. K(i) was 77 and 65 nM for inhibition of savinase activity by His(6)-rBASI and sBASI, respectively.

Plant alpha-amylase inhibitors and their interaction with insect alpha-amylases

Insect pests and pathogens (fungi, bacteria and viruses) are responsible for severe crop losses. Insects feed directly on the plant tissues, while the pathogens lead to damage or death of the plant. Plants have evolved a certain degree of resistance through the production of defence compounds, which may be aproteic, e.g. antibiotics, alkaloids, terpenes, cyanogenic glucosides or proteic, e.g. chitinases, beta-1,3-glucanases, lectins, arcelins, vicilins, systemins and enzyme inhibitors. The enzyme inhibitors impede digestion through their action on insect gut digestive alpha-amylases and proteinases, which play a key role in the digestion of plant starch and proteins. The natural defences of crop plants may be improved through the use of transgenic technology. Current research in the area focuses particularly on weevils as these are highly dependent on starch for their energy supply. Six different alpha-amylase inhibitor classes, lectin-like, knottin-like, cereal-type, Kunitz-like, gamma-purothionin-like and thaumatin-like could be used in pest control. These classes of inhibitors show remarkable structural variety leading to different modes of inhibition and different specificity profiles against diverse alpha-amylases. Specificity of inhibition is an important issue as the introduced inhibitor must not adversely affect the plant's own alpha-amylases, nor the nutritional value of the crop. Of particular interest are some bifunctional inhibitors with additional favourable properties, such as proteinase inhibitory activity or chitinase activity. The area has benefited from the recent determination of many structures of alpha-amylases, inhibitors and complexes. These structures highlight the remarkable variety in structural modes of alpha-amylase inhibition. The continuing discovery of new classes of alpha-amylase inhibitor ensures that exciting discoveries remain to be made. In this review, we summarize existing knowledge of insect alpha-amylases, plant alpha-amylase inhibitors and their interaction. Positive results recently obtained for transgenic plants and future prospects in the area are reviewed.

Specific inhibition of barley alpha-amylase 2 by barley alpha-amylase/subtilisin inhibitor depends on charge interactions and can be conferred to isozyme 1 by mutation

alpha-Amylase 2 (AMY2) and alpha-amylase/subtilisin inhibitor (BASI) from barley bind with Ki = 0.22 nM. AMY2 is a (beta/alpha)8-barrel enzyme and the segment Leu116-Phe143 in domain B (Val89-Ile152), protruding at beta-strand 3 of the (beta/alpha)8-barrel, was shown using isozyme hybrids to be crucial for the specificity of the inhibitor for AMY2. In the AMY2-BASI crystal structure [F. Vallée, A. Kadziola, Y. Bourne, M. Juy, K. W. Rodenburg, B. Svensson & R. Haser (1998) Structure 6, 649-659] Arg128AMY2 forms a hydrogen bond with Ser77BASI, while Asp142AMY2 makes a salt-bridge with Lys140BASI. These two enzyme residues are substituted by glutamine and asparagine, respectively, to assess their contribution in binding of the inhibitor. These mutations were performed in the well-expressed, inhibitor-sensitive hybrid barley alpha-amylase 1 (AMY1)-(1-90)/AMY2-(90-403) with Ki = 0.33 nM, because of poor production of AMY2 in yeast. In addition Arg128, only found in AMY2, was introduced into an AMY1 context by the mutation T129R/K130P in the inhibitor-insensitive hybrid AMY1-(1-161)/AMY2-(161-403). The binding energy was reduced by 2.7-3.0 kcal.mol-1 as determined from Ki after the mutations R128Q and D142N. This corresponds to loss of a charged interaction between the protein molecules. In contrast, sensitivity to the inhibitor was gained (Ki = 7 microM) by the mutation T129R/K130P in the insensitive isozyme hybrid. Charge screening raised Ki 14-20-fold for this latter mutant, AMY2, and the sensitive isozyme hybrid, but only twofold for the R128Q and D142N mutants. Thus electrostatic stabilization was effectively introduced and lost in the different mutant enzyme-inhibitor complexes and rational engineering using an inhibitor recognition motif to confer binding to the inhibitor mimicking the natural AMY2-BASI complex.

Phage-displayed peptide ligands for pancreatic alpha-amylase cross-react with barley alpha-amylase

Peptide ligands that bind to pancreatic alpha-amylase were isolated from bacteriophage libraries displaying random 15-mer peptides by iterative affinity selection and amplification. The DNA sequences of selected clones from the final round of biopanning were determined. The two phage-display ligands with high-binding activities contained a high content of Arg, Tyr, and Trp residues with the short consensus sequence Arg-X-Tyr-Trp. These clones were shown to exhibit comparable binding interactions toward barley alpha-amylase based on transducing units titering and measurement of the dissociation constants.

Barley alpha-amylase bound to its endogenous protein inhibitor BASI: crystal structure of the complex at 1.9 A resolution

BACKGROUND

Barley alpha-amylase is a 45 kDa enzyme which is involved in starch degradation during barley seed germination. The released sugars provide the plant embryo with energy for growth. The major barley alpha-amylase isozyme (AMY2) binds with high affinity to the endogenous inhibitor BASI (barley alpha-amylase/subtilisin inhibitor) whereas the minor isozyme (AMY1) is not inhibited. BASI is a 19.6 kDa bifunctional protein that can simultaneously inhibit AMY2 and serine proteases of the subtilisin family. This inhibitor may therefore prevent degradation of the endosperm starch during premature sprouting and protect the seed from attack by pathogens secreting proteases.

RESULTS

The crystal structure of AMY2 in complex with BASI was determined and refined at 1.9 A resolution. BASI consists of a 12-stranded beta-barrel structure which belongs to the beta-trefoil fold family and inhibits AMY2 by sterically occluding access of the substrate to the active site of the enzyme. The AMY2-BASI complex is characterized by an unusual completely solvated calcium ion located at the protein-protein interface.

CONCLUSIONS

The AMY2-BASI complex represents the first reported structure of an endogenous protein-protein complex from a higher plant. The structure of the complex throws light on the strict specificity of BASI for AMY2, and shows that domain B of AMY2 contributes greatly to the specificity of enzyme-inhibitor recognition. In contrast to the three-dimensional structures of porcine pancreatic alpha-amylase in complex with proteinaceous inhibitors, the AMY2-BASI structure reveals that the catalytically essential amino acid residues of the enzyme are not directly bound to the inhibitor. Binding of BASI to AMY2 creates a cavity, exposed to the external medium, that is ideally shaped to accommodate an extra calcium ion. This feature may contribute to the inhibitory effect, as the key amino acid sidechains of the active site are in direct contact with water molecules which are in turn ligated to the calcium ion.

Binding of urokinase-type plasminogen activator-plasminogen activator inhibitor-1 complex to the endocytosis receptors alpha2-macroglobulin receptor/low-density lipoprotein receptor-related protein and very-low-density lipoprotein receptor involves basic residues in the inhibitor

The complex of the type-1 plasminogen activator inhibitor (PAI-1) and its target proteinases, the urokinase and tissue-type plasminogen activators (uPA and tPA), but not the free components, bind with high affinity to the endocytosis receptors alpha2-macroglobulin receptor/low-density lipoprotein receptor-related protein (alpha2MR/LRP) and very-low-density lipoprotein receptor (VLDLR). To characterize the molecular interaction between the complexes and the receptors, alanine codons were introduced into the human PAI-1 cDNA to replace the four basic residues, Arg-78, Lys-82, Arg-120 and Lys-124, as double mutations. The purified recombinant mutant proteins, rPAI-1/R78A-K124A and rPAI-1/K82A-R120A, produced by the yeast Pichia pastoris, were indistinghuisable from wild-type recombinant and natural human PAI-1 with respect to inhibitory activity against uPA, stability of SDS-resistant complexes with uPA, and vitronectin binding. Radiolabelled mutant uPA.PAI-1 complexes bound with a 10- to 20-fold, and 3- to 7-fold reduced affinity to purified alpha2MR/LRP and VLDLR respectively. alpha2MR/LRP-mediated endocytosis of the mutant complexes by COS-1 cells was reduced to 48 and 38% of the level of endocytosis of wild-type PAI-1. Binding of the mutant complexes to the uPA receptor was not affected. These findings suggest that the binding mode of the uPA.PAI-1 complex to both alpha2MR/LRP and VLDLR is similar. The four residues are surface exposed in the region defined by alpha-helix D and beta-strand 1A in the serine protease inhibitor (serpin) structure. Our study represents the first identification of residues in a surface region implicated in molecular recognition of protease.serpin complexes by endocytosis receptors of the low-density lipoprotein receptor family.