Purification and properties of phaseolamin, an inhibitor of alpha-amylase, from the kidney bean, Phaseolus vulgaris.

Kidney beans, Phaseolus vulgaris, contain a proteinaceous inhibitor of alpha-amylase, which we have named phaseolamin. The inhibitor has been purified to homogeneity by conventional protein fractionation methods involving heat treatment, dialysis, and chromatography on DEAE-cellulose, Sephadex G-100, and CM-cellulose. Phaseolamin is specific for animal alpha-amylases, having no activity towards the corresponding plant, bacterial, and fungal enzymes, or any other hydrolytic enzyme tested. Optimal inhibitory activity is expressed during preincubation of enzyme and inhibitor at pH 5.5 and 37 degrees. Substrate prevents inhibition. Measurement of the stoichiometry on inhibition showed that a 1:1 complex of alpha-amylase and inhibitor is formed. Complex formation was demonstrated by chromatography on Sephadex G-100. The phaseolamin-amylase complex is dissociated at low pH values, apparently as a result of destruction of the enzyme; the complex cannot be dissociated by other conditions unfavorable for inhibition (low temperature or high pH). Phaseolamin inhibits hog pancreatic alpha-amylase in a noncompetitive manner.     

A chimera-like alpha-amylase inhibitor suggesting the evolution of Phaseolus vulgaris alpha-amylase inhibitor

White kidney bean (Phaseolus vulgaris) contains two kinds of alpha-amylase inhibitors, one heat-stable (alpha AI-s) and one heat-labile (alpha AI-u). alpha AI-s has recently been revealed to be a tetrameric complex, alpha(2)beta(2), with two active sites [Kasahara et al. (1996) J. Biochem. 120, 177-183]. The present study was undertaken to reveal the molecular features of alpha AI-u, which is composed of three kinds of subunits, alpha, beta, and gamma. The gamma-subunit, in contrast to the alpha- and beta-subunits that are indistinguishable from the alpha- and beta-subunits of alpha AI-s, was found to correspond to a subunit of an alpha-amylase inhibitor-like protein, which has been identified as an inactive, evolutionary intermediate between arcelin and the alpha-amylase inhibitor in a P. vulgaris defense protein family. The polypeptide molecular weight of alpha AI-u determined by the light-scattering technique, together with the polypeptide molecular weights of the subunits, suggests that alpha AI-u is a trimeric complex, alpha beta gamma. The inhibition of alpha AI-u by increasing amounts of porcine pancreatic alpha-amylase (PPA) indicates that an inactive 1:1 complex is formed between alpha AI-u and PPA. Molecular weight estimation of the complex by the light-scattering technique confirmed that it is a complex of alpha AI-u with one PPA molecule. Thus it seems probable that alpha AI-u is an evolutionary intermediate of the P. vulgaris alpha-amylase inhibitor.     

Inhibitory specificity and insecticidal selectivity of alpha-amylase inhibitor from Phaseolus vulgaris

The primary structure and proteolytic processing of the alpha-amylase isoinhibitor alpha AI-1 from common bean (Phaseolus vulgaris cv. Magna) was determined by protein chemistry techniques. The inhibitory specificity of alphaAI-1 was screened with a panel of the digestive alpha-amylases from 30 species of insects, mites, gastropod, annelid worm, nematode and fungal phytopathogens with a focus on agricultural pests and important model species. This in vitro analysis showed a selective inhibition of alpha-amylases from three orders of insect (Coleoptera, Hymenoptera and Diptera) and an inhibition of alpha-amylases of the annelid worm. The inhibitory potential of alphaAI-1 against several alpha-amylases was found to be modulated by pH. To understand how alphaAI-1 discriminates among closely related alpha-amylases, the sequences of the alpha-amylases sensitive, respectively, insensitive to alphaAI-1 were compared, and the critical determinants were localized on the spatial alpha-amylase model. Based on the in vitro analysis of the inhibitory specificity of alphaAI-1, the in vivo activity of the ingested alphaAI-1 was demonstrated by suppression of the development of the insect larvae that expressed the sensitive digestive alpha-amylases. The first comprehensive mapping of alphaAI-1 specificity significantly broadens the spectrum of targets that can be regulated by alpha-amylase inhibitors of plant origin, and points to potential application of these protein insecticides in plant biotechnologies.     

Selective inhibition of histidine-modified pancreatic alpha-amylase by proteinaceous inhibitor from Phaseolus vulgaris

Chemical modification of two histidine residues of porcine pancreatic alpha-amylase (EC 3.2.1.1) by diethyl pyrocarbonate in the presence of a high concentration of maltotriose caused a decrease of amylase activity and an increase of maltosidase activity (hydrolysis of p-nitrophenyl-alpha-maltoside). By binding a proteinaceous inhibitor from Phaseolus vulgaris (white kidney bean) with the modified enzyme, the amylase activity was further decreased but the maltosidase activity was retained to about 100% that of the native enzyme. Both amylase and maltosidase activities of the native enzyme were almost completely inhibited by the proteinaceous inhibitor. The increase of maltosidase activity by histidine modification was due to an increase of kcat, whereas the Km value was not changed; but binding of the proteinous inhibitor affected mainly the Km value of the modified enzyme.     

Isolation and characterization of the subunits of Phaseolus vulgaris alpha-amylase inhibitor.

An alpha-amylase inhibitor (PHA-I) of the white kidney bean (Phaseolus vulgaris) was found to be composed of two kinds of subunits and they were isolated on a size-exclusion column by HPLC under denaturing conditions. The alpha-subunit was free from tryptophan and cysteine and the beta-subunit contained no methionine or cysteine. There was no marked resemblance in tryptic peptide map between these subunit polypeptides. The alpha-subunit contained 28% by weight of carbohydrate, mainly made up of high mannose-type oligosacharides, whereas the sugar moiety of the beta-subunit amounted to 7% by weight and seemed to be predominantly composed of xylomannose-type oligosaccharides. By SDS-PAGE following deglycosylation, the molecular weights of the polypeptides of alpha- and beta-subunits were shown to be 7,800 and 14,000, respectively. These values were consistent with molecular sizes obtained for alpha- and beta-subunits by gel permeation HPLC in 6 M guanidine hydrochloride. The molecular weight of the native PHA-I, 28,800, obtained by gel permeation HPLC under non-denaturing conditions, suggested a heterodimeric structure for PHA-I.     

Isolation and characterization of lectins from kidney beans (Phaseolus vulgaris)

The bioactive properties of lectins obtained from raw and canned red kidney bean (Phaseolus vulgaris) were studied to determine the changes in their bioactivity during the canning process. Phytohaemagglutinin (PHA) was extracted using Affi-gel Blue gel and thyroglobulin-Sepharose and had a molecular weight of 32 kDa. Both the raw and the canned kidney beans possessed the ability to agglutinate red blood cells and inhibit α-glucosidase. The activity found in the canned beans was similar to that from the in the raw kidney beans. However, the amount of lectin that could be extracted from thyroglobulin-Sepharose was much less in the canned samples than in the raw kidney bean samples. The extracted lectin from the raw kidney beans was also subjected to a heating and cooling treatment using a differential scanning calorimeter. The lectin had a nonset denaturation temperature of 77.76 °C and it did not renature upon cooling. In this study, we demonstrated that extracts from raw red kidney bean and canned red kidney bean contain bioactive compounds capable of inhibiting HIV-1 RT in vitro.     

Identification of essential amino acid residues in valine dehydrogenase from Streptomyces albus

Cys-29 and Cys-251 of Streptomyces albus valine dehydrogenase (ValDH) were highly conserved in the corresponding region of NAD(P)(+)-dependent amino acid dehydroganase sequences. To ascertain the functional role of these cysteine residues in S. albus ValDH, site-directed mutagenesis was performed to change each of the two residues to serine. Kinetic analyses of the enzymes mutated at Cys-29 and Cys-251 revealed that these residues are involved in catalysis. We also constructed mutant ValDH by substituting valine for leucine at 305 by site-directed mutagenesis. This residue was chosen, because it has been proposed to be important for substrate discrimination by phenylalanine dehydrogenase (PheDH) and leucine dehydrogenase (LeuDH). Kinetic analysis of the V305L mutant enzyme revealed that it is involved in the substrate binding site. However it displayed less activity than the wild type enzyme toward all aliphatic and aromatic amino acids tested.     

Porcine pancreatic alpha-amylase inhibition by the kidney bean (Phaseolus vulgaris) inhibitor (alpha-AI1) and structural changes in the alpha-amylase inhibitor complex

Porcine pancreatic alpha-amylase (PPA) is inhibited by the red kidney bean (Phaseolus vulgaris) inhibitor alpha-AI1 [Eur. J. Biochem. 265 (1999) 20]. Inhibition kinetics were carried out using DP 4900-amylose and maltopentaose as substrate. As shown by graphical and statistical analysis of the kinetic data, the inhibitory mode is of the mixed noncompetitive type whatever the substrate thus involving the EI, EI2, ESI and ESI2 complexes. This contrast with the E2I complex obtained in the crystal and with biophysical studies. Such difference very likely depends on the [I]/[E] ratio. At low ratio, the E2I complex is favoured; at high ratio the EI, ESI and EI2 complexes are formed. The inhibition model also differs from those previously proposed for acarbose [Eur. J. Biochem. 241 (1996) 787 and Eur. J. Biochem. 252 (1998) 100]. In particular, with alpha-AI1, the inhibition takes place only when PPA and alpha-AI are preincubated together before adding the substrate. This indicates that the abortive PPA-alphaAI1 complex is formed during the preincubation period. One additional carbohydrate binding site is also demonstrated yielding the ESI complex. Also, a second protein binding site is found in EI2 and ESI2 abortive complexes. Conformational changes undergone by PPA upon alpha-AI1 binding are shown by higher sensitivity to subtilisin attack. From X-ray analysis of the alpha-AI1-PPA complex (E2I), the major interaction occurs with two hairpin loops L1 (residues 29-46) and L2 (residues 171-189) of alpha-AI1 protruding into the V-shaped active site of PPA. The hydrolysis of alpha-AI1 that accounts for the inhibitory activity is reported.     

Unfolding and refolding of leucoagglutinin (PHA-L), an oligomeric lectin from kidney beans (Phaseolus vulgaris)

The unfolding and refolding of Phaseolus vulgaris Leucoagglutinin, a homotetrameric legume lectin, was studied at pH 2.5 and 7.2 using fluorescence, far- and near-UV circular dichroism (CD) spectroscopy, 8-anilino-1-naphthalene sulfonate (ANS) binding and FPLC techniques. This protein was found to refold even at pH 2.5 and also exhibited high refolding yield around 60% at pH 2.5 and 85% at pH 7.2. The refolding at pH 2.5 takes place with the formation of a dimeric intermediate. Although the hydrodynamic radius of the completely renatured protein and the dimer at pH 2.5 was found to be same, the ANS binding as well as far-UV CD spectra of the two were different. The denaturation kinetics at pH 2.5 followed single exponential pattern with the rate of denaturation being independent of protein concentration. The renaturation kinetics on the other hand was dependent on the protein concentration providing further evidence of an intermediate state during refolding. From these experiments the folding pathway of the protein at pH 2.5 was proposed.     

Insecticidal activity of an alpha-amylase inhibitor-like protein resembling a putative precursor of alpha-amylase inhibitor in the common bean, Phaseolus vulgaris L.

alpha-Amylase inhibitor (alphaAI) in the common bean, Phaseolus vulgaris L., protects seeds from insect pests such as the cowpea weevil (Callosobruchus maculatus) and the azuki bean weevil (C. chinensis). Cultivars which lack alphaAI still show resistance to both bruchids. These cultivars have a glycoprotein that reacts with anti-alphaAI-1 antibodies. The glycoprotein with a molecular mass of 29 kDa (Gp29) was purified and the encoding gene was isolated. The primary structure of Gp29 is the same as alpha-amylase inhibitor-like protein (AIL) from which the encoding gene has already been isolated. AIL resembles a putative precursor of alphaAI, even though it does not form the active inhibitor. However, AIL has some inhibitory effect on the growth of C. maculatus but not C. chinensis. The presence of AIL alone is insufficient to explain the bruchid resistance of common bean cultivars lacking alpha-AI. Common bean seeds appear to contain several factors responsible for the bruchid resistance.     

Activation of bean (Phaseolus vulgaris) alpha-amylase inhibitor requires proteolytic processing of the proprotein.

Seeds of the common bean (Phaseolus vulgaris) contain a plant defense protein that inhibits the alpha-amylases of mammals and insects. This alpha-amylase inhibitor (alpha AI) is synthesized as a proprotein on the endoplasmic reticulum and is proteolytically processed after arrival in the protein storage vacuoles to polypeptides of relative molecular weight (M(r)) 15,000 to 18,000. We report two types of evidence that proteolytic processing is linked to activation of the inhibitory activity. First, by surveying seed extracts of wild accessions of P. vulgaris and other species in the genus Phaseolus, we found that antibodies to alpha AI recognize large (M(r) 30,000-35,000) polypeptides as well as typical alpha AI processing products (M(r) 15,000-18,000). Alpha AI activity was found in all extracts that had the typical alpha AI processed polypeptides, but was absent from seed extracts that lacked such polypeptides. Second, we made a mutant alpha AI in which asparagine-77 is changed to aspartic acid-77. This mutation slows down the proteolytic processing of pro-alpha AI when the gene is expressed in tobacco. When pro-alpha AI was separated from mature alpha AI by gel filtration, pro-alpha AI was found not to have alpha-amylase inhibitory activity. We interpret these results to mean that formation of the active inhibitor is causally related to proteolytic processing of the proprotein. We suggest that the polypeptide cleavage removes a conformational constraint on the precursor to produce the biochemically active molecule.     

Purification of the phytohemagglutinin family of proteins from red kidney beans (Phaseolus vulgaris) by affinity chromatography.

Half-gram quantities of phytohemagglutinin lectins are purified from saline extracts of red kidney beans (Phaseolus vulgaris) by affinity absorption on porcine thyroglobulin-Sepharose. All of the mitogenic and erythroagglutinin activity of the saline extract is removed by this absorbent, and 74% of the original erythroagglutinating activity elutes from the affinity absorbent representing a 25-fold purification. Five distinct proteins appear in the polyacrylamide gel electrophoresis of the affinity absorbent eluate. Although all five proteins specifically bind to porcine thyroglobulin, the cathodal migrating proteins bind more strongly than the anodal migrating proteins. The most cathodal proteins are potent erythroagglutinins. This simple, efficient method is used to prepare all the active components of the phytohemagglutinin family in large yield and high purity.     

Purification and characterization of a thermostable beta-galactosidase from kidney beans (Phaseolus vulgaris L.) cv. PDR14

Using five different steps, beta-Galactosidase has been purified from kidney beans to apparent electrophoretic homogeneity with approximately 90-fold purification with a specific activity of 281 units mg-1 protein. A single band was observed in native PAGE. Activity staining of the native gel with 5-bromo 4-chloro 3-indoxyl beta-D-galactopyranoside (X-Gal) at pH 4.0 also produced a single band. Analytical gel filtration in Superdex G-75 revealed the molecular mass of the native protein to be approximately 75 kD. 10% SDS-PAGE under reducing conditions showed two subunits of molecular masses, 45 and 30 kD, respectively. Hence, beta-galactosidase from kidney beans is a heterodimer. A typical protein profile with lambda max at 280 nm was observed and A280/A260 ratio was 1.52. The N-terminal sequence of the 45 kD band showed 86% sequence homology with an Arabidopsis thaliana and 85% with Lycopersicon esculentum putative beta-galactosidase sequences. The Electrospray Mass Spectrometric analysis of this band also revealed a peptide fragment that had 90% sequence homology with an Arabidopsis thaliana putative beta-galactosidase sequence. The N-terminal sequencing of the 30 kD band as well as mass spectrometric analysis both by MALDI-TOF and ES MS revealed certain sequences that matched with phytohemagglutinin of kidney beans. The optimum pH of the enzyme was 4.0 and it hydrolysed o- and p-nitrophenyl beta-D galactopyranoside with a Km value of 0.63 mmol/L and 0.74 mmol/L, respectively. The energy of activation calculated from the Arrhenius equation was 14.8 kcal/mol enzyme site. The enzyme was found to be comparatively thermostable showing maximum activity at 67 degrees C. Thermal denaturation of the enzyme at 65 degrees C obeys single exponential decay with first order-rate constant 0.105 min-1. Galactose, a hydrolytic product of this enzyme was a competitive inhibitor with a Ki of 2.7 mmol/L.     

Identification of amino acid residues essential for onion lachrymatory factor synthase activity

Lachrymatory factor synthase (LFS), an enzyme essential for the synthesis of the onion lachrymatory factor (propanethial S-oxide), was identified in 2002. This was the first reported enzyme involved in the production of thioaldehyde S-oxides via an intra-molecular H(+) substitution reaction, and we therefore attempted to identify the catalytic amino acid residues of LFS as the first step in elucidating the unique catalytic reaction mechanism of this enzyme. A comparison of the LFS cDNA sequences among lachrymatory Allium plants, a deletion analysis and site-directed mutagenesis enabled us to identify two amino acids (Arg71 and Glu88) that were indispensable to the LFS activity. Homology modeling was performed for LFS/23-169 on the basis of the template structure of a pyrabactin resistance 1-like protein (PYL) which had been selected from a BLASTP search on SWISS-MODEL against LFS/23-169. We identified in the modeled structure of LFS a pocket corresponding to the ligand-binding site in PYL, and Arg71 and Glu88 were located in this pocket.     

Identification of essential amino acid residues in the Sinorhizobium meliloti glucosyltransferase ExoM

ExoM is a beta(1-4)-glucosyltransferase involved in the assembly of the repeat unit of the exopolysaccharide succinoglycan from Sinorhizobium meliloti. By comparing the sequence of ExoM to those of other members of the Pfam Glyco Domain 2 family, most notably SpsA (Bacillus subtilis) for whom the three-dimensional structure has been resolved, three potentially important aspartic acid residues of ExoM were identified. Single substitutions of each of the Asp amino acids at positions 44, 96, and 187 with Ala resulted in the loss of mutant recombinant protein activity in vitro as well as the loss of succinoglycan production in an in vivo rescue assay. Mutants harboring Glu instead of Asp-44 or Asp-96 possessed no in vitro activity but could restore succinoglycan production in vivo. However, replacement of Asp-187 with Glu completely inactivated ExoM as judged by both the in vitro and in vivo assays. These results indicate that Asp-44, Asp-96, and Asp-187 are essential for the activity of ExoM. Furthermore, these data are consistent with the functions proposed for each of the analogous aspartic acids of SpsA based on the SpsA-UDP structure, namely, that Asp-44 and Asp-96 are involved in UDP substrate binding and that Asp-187 is the catalytic base in the glycosyltransferase reaction.