Complete sequence-specific 1H nuclear magnetic resonance assignments for the alpha-amylase polypeptide inhibitor tendamistat from Streptomyces tendae

The 1H nuclear magnetic resonance (n.m.r.) spectrum of the alpha-amylase inhibitor Tendamistat was completely assigned with the use of phase-sensitive homonuclear two-dimensional n.m.r. The assignments include the non-labile protons of the 74 amino acid residues as well as the labile protons which exchange sufficiently slowly to be observed in H2O solution. The proton chemical shifts are listed at 50 degrees C and pH 3.2, which coincides with the conditions used for the determination of the three-dimensional structure of Tendamistat.     

Determination of the complete three-dimensional structure of the alpha-amylase inhibitor tendamistat in aqueous solution by nuclear magnetic resonance and distance geometry

The complete three-dimensional structure of the alpha-amylase inhibitor Tendamistat in aqueous solution was determined by 1H nuclear magnetic resonance and distance geometry calculations using the program DISMAN. Compared to an earlier, preliminary determination of the polypeptide backbone conformation, stereo-specific assignments were obtained for 41 of the 89 prochiral groups in the protein, and a much more extensive set of experimental constraints was collected, including 842 distance constraints from nuclear Overhauser effects and over 100 supplementary constraints from spin-spin coupling constants and the identification of intramolecular hydrogen bonds. The complete protein molecule, including the amino acid side-chains is characterized by a group of nine structures corresponding to the results of the nine DISMAN calculations with minimal residual error functions. The average of the pairwise minimal root-mean-square distances among these nine structures is 0.85 A for the polypeptide backbone, and 1.52 A for all the heavy atoms. The procedures used for the structure determination are described and a detailed analysis is presented of correlations between the experimental input data and the precision of the structure determination.     

Proteolytic enzymes from recombinant Streptomyces lividans TK24

Different proteases from the culture fluids of recombinant Streptomyces lividans strains were isolated. Several individual proteases were separated and characterized. A chymotrypsin-chylike activity (CLA) was identified that specifically degrades a fusion protein between the alpha-amylase inhibitor from S. tendae (Tendamistat, HOE467) and proinsulin from the monkey Macaca fascicularis. The effective chemical inhibition of the degrading enzyme is demonstrated.     

小麦抗虫α-淀粉酶抑制因子成熟蛋白编码基因序列分析

对17份小麦和山羊草材料的小麦抗虫24kD-α-淀粉酶抑制因子成熟蛋白编码基因进行了分离克隆和序列分析。结果发现,在二倍体材料中α-淀粉酶抑制因子由单个基因编码,而在普通小麦中是以多拷贝的形式存在。从中得到17个24kD-α-淀粉酶抑制因子基因,其中2个来自普通小麦与1个来自粗山羊草的基因编码的抑制因子与WDAI-0-19的氨基酸序列完全相同,为同一蛋白。在普通小麦中得到1个编码蛋白质与WDAI-0-53十分相似的基因。序列分析表明,24kD-α-淀粉酶抑制因子成熟蛋白编码基因在序列大小与核酸组成上都十分相似,一致性达到91.2%。这说明小麦和山羊草中24kD-α-淀粉酶抑制因子基因可能起源于相同原始基因。     

Correlation of LUMO localization with the alpha-amylase inhibition constant in a Tendamistat-based series of linear and cyclic peptides

The glycosidase alpha-amylase is responsible for the hydrolysis of alpha(1-->4) glycosidic linkages found in dietary starch as one means for controlling blood sugar level. The effect of alpha-amylase is detrimental, however, in the disease state diabetes mellitus, where blood glucose levels are elevated due to a biochemical defect. Inhibition of the enzyme's activity would reduce glucose absorption by the small intestine. Our objective was to develop small peptides based on essential binding elements of the natural protein inhibitor, Tendamistat. These smaller analogs may be better studied structurally and conformationally to help us understand molecular-level interactions. In addition, we have been able to correlate the activity of our compounds with the lowest unoccupied molecular orbital (LUMO) localization in energy-minimized conformations. The positive charge/LUMO of most active inhibitors is localized on the central Arg residue of the required triplet. This provides a predictive model for the design of active molecules.     

The primary structure of alpha-amylase inhibitor Z-2685 from Streptomyces parvullus FH-1641. Sequence homology between inhibitor and alpha-amylase

The native and oxidized alpha-amylase inhibitor Z-2685, isolated from the culture medium of Streptomyces parvullus FH-1641, and its overlapping cleavage products were degraded by the automatic Edman technique. Digestion was carried out with pepsin, thermolysin and trypsin. The alpha-amylase inhibitor is a polypeptide consisting of 76 amino acids with a molecular mass of 8 129 Da. With the exception of methionine and lysine, all naturally occurring amino acids are present. It is interesting that identical regions exist, in particular the sequence Trp-Arg-Tyr common to all four known microbial inhibitor sequences. We believe that the side chains of these three amino acids are important for interacting with the alpha-amylase molecule. Computer alignment enabled us to show a possible binding region in the alpha-amylase molecule which might react with the inhibitors. Furthermore, homology exists to mammalian alpha-amylases. This result is explained by the assumption that the inhibitor evolved from a duplication of the original gene of the enzyme.     

Detection of single nucleotide polymorphisms in 24 kDa dimeric alpha-amylase inhibitors from cultivated wheat and its diploid putative progenitors

Seventeen new genes encoding 24 kDa family dimeric alpha-amylase inhibitors had been characterized from cultivated wheat and its diploid putative progenitors. And the different alpha-amylase inhibitors in this family, which were determined by coding regions single nucleotide polymorphisms (cSNPs) of their genes, were investigated. The amino acid sequences of 24 kDa alpha-amylase inhibitors shared very high coherence (91.2%). It indicated that the dimeric alpha-amylase inhibitors in the 24 kDa family were derived from common ancestral genes by phylogenetic analysis. Eight alpha-amylase inhibitor genes were characterized from one hexaploid wheat variety, and clustered into four subgroups, indicating that the 24 kDa dimeric alpha-amylase inhibitors in cultivated wheat were encoded by multi-gene. Forty-five cSNPs, including 35 transitions and 10 transversions, were found, and resulted in a total of ten amino acid changes. The cSNPs at the first site of a codon cause much more nonsynonymous (92.9%) than synonymous mutations, while nonsynonymous and synonymous mutations were almost equal when the cSNPs were at the third site. It was observed that there was Ile105 instead of Val105 at the active region Val104-Val105-Asp106-Ala107 of the alpha-amylase inhibitor by cSNPs in some inhibitors from Aegilops speltoides, diploid and hexaploid wheats.     

Isolation and structure elucidation of an alpha-amylase inhibitor, AI-3688, from Streptomyces aureofaciens

A novel polypeptide inhibitor, AI-3688, which acts upon human pancreatic alpha-amylase, was isolated from fermentation broth of Streptomyces aureofaciens. The purified peptide contains no unusual amino acids. Its Mr is 3936. The primary structure of AI-3688 was elucidated by automatic Edman degradation of the native or modified inhibitor. Two intramolecular cysteines form a disulphide bridge, thus creating a ring structure consisting of 17 amino acids. Strong sequence homology also exists to another microbial alpha-amylase inhibitor, tendamistat (HOE 467). This paper discusses the role of a common partial sequence, -Gln-Ser-Trp-Arg-Tyr-, present in the loop of both inhibitors as the active site of microbial peptide alpha-amylase inhibitors.     

alpha-Amylase inhibitor from fungus Cladosporium herbarum F-828

A strain of fungus Cladosporium herbarum extracellularly produced an inhibitor specific for mammalian alpha-amylase. The inhibitor was purified 81-fold by freeze-thawing, heat treatment, and column chromatography on DEAE-cellulose, Sephadex G-75, DEAE-Sephacel, and Bio-Gel P-100. An apparent molecular weight of approximately 18,000 was estimated for the inhibitor using Bio-Gel P-100 filtration. The purified inhibitor preparation was a glycoprotein containing about 10% carbohydrate. The amino acid analysis of the inhibitor showed abundances of Gly, Asp, Glu, Ser, Ala, and Thr residues. The inhibitor was stable between pH 5 and 12 at 4 degrees C, and below 80 degrees C at pH 7.0. A binary complex formation out of equimolar amounts of the inhibitor and alpha-amylase, was demonstrated by polyacrylamide gel electrophoresis, and Bio-Gel P-100 chromatography. Kinetic studies exhibited that the inhibitor noncompetitively inhibited the enzyme reaction with a Ki value of 2.3 approximately 4.8 x 10(-10) M, by combining with the enzyme molecule at a different site from the substrate binding site.     

Cloning and functional expression of the gene encoding an inhibitor against <Emphasis Type="Italic">Aspergillus flavus</Emphasis> α-amylase,a novel seed lectin from <Emphasis Type="Italic">Lablab purpureus</Emphasis> (<Emphasis Type="Italic">Dolichos lablab</Emphasis>)

Maize is one of the more important agricultural crops in the world and, under certain conditions, prone to attack from pathogenic fungi. One of these, Aspergillus flavus, produces toxic and carcinogenic metabolites, called aflatoxins, as byproducts of its infection of maize kernels. The alpha-amylase of A. flavus is known to promote aflatoxin production in the endosperm of these infected kernels, and a 36-kDa protein from the Lablab purpureus, denoted AILP, has been shown to inhibit alpha-amylase production and the growth of A. flavus. Here, we report the isolation of six full-length labAI genes encoding AILP and a detailed analysis of the activities of the encoded proteins. Each of the six labAI genes encoded sequences of 274 amino acids, with the deduced amino acid sequences showing approximately 95-99% identity. The sequences are similar to those of lectin members of a legume lectin-arcelin-alpha-amylase inhibitor family reported to function in plant resistance to insect pests. The labAI genes did not show any of the structures characteristic of conserved structures identified in alpha-amylase inhibitors to date. The recombinant proteins of labAI-1 and labAI-2 agglutinated human red blood cells and inhibited A. flavus alpha-amylase in a manner similar to that shown by AILP. These data indicate that labAI genes are a new class of lectin members in legume seeds and that their proteins have both lectin and alpha-amylase inhibitor activity. These results are a valuable contribution to our knowledge of plant-pathogen interactions and will be applicable for developing protocols aimed at controlling A. flavus infection.     

New dimeric inhibitor of heterologous alpha-amylases encoded by a duplicated gene in the short arm of chromosome 3B of wheat (Triticum aestivum L.)

A new wheat dimeric alpha-amylase inhibitor, designated WDAI-3, has been characterized. WDAI-3 is a homodimeric protein active against alpha-amylase from human saliva and from the insect Tenebrio molitor, but inactive against that from pig pancreas or against trypsin. Its N-terminal amino acid sequence is closer to those of the wheat dimeric inhibitors 0.19 and 0.53 (89-91% identical positions in 44 residues) than to that of the monomeric 0.28 inhibitor (69% identical positions). Iha-B1-2, the gene encoding the new inhibitor, is located in the short arm of chromosome 3B, where it is part of an intrachromosomal gene duplication that also codes for the 0.53 inhibitor.     

Complete nucleotide sequence of a thermophilic alpha-amylase gene: homology between prokaryotic and eukaryotic alpha-amylases at the active sites

The nucleotide sequence of a thermophilic, liquefying alpha-amylase gene cloned from B. stearothermophilus was determined. The NH2-terminal amino acid sequence analysis of the B. stearothermophilus alpha-amylase confirmed that the reading frame of the gene consisted of 1,644 base pairs (548 amino acids). The B. stearothermophilus alpha-amylase had a signal sequence of 34 amino acids, which was cleaved at exactly the same site in E. coli. The mature enzyme contained two cysteine residues, which might play an important role in maintenance of a stable protein conformation. Comparison of the amino acid sequence inferred from the B. stearothermophilus alpha-amylase gene with those inferred from other bacterial liquefying alpha-amylase genes and with the amino acid sequences of eukaryotic alpha-amylases showed three homologous sequences in the enzymatically functional regions.     

Biophysical characterization of α-amylase inhibitor Parvulustat (Z-2685) and comparison with Tendamistat (HOE-467)

Parvulustat is a small, highly active proteinaceous α-amylase inhibitor whose high-resolution NMR structure was recently solved in Frankfurt. Here, we present its biochemical and biophysical characterization. Several spectroscopic methods such as UV, fluorescence and CD were utilized to extract conformational changes upon modification of pH, temperature and chemical denaturant. Parvulustat revealed native like behavior over a wide range of denaturizing agents as reflected in terms of activity and thermodynamic data. In addition, spectroscopic and thermodynamic properties of Parvulustat were compared to the well-characterized Tendamistat. Despite the overall structural similarity, the thermodynamic stability of the two proteins is different. Our analysis led to the conclusion that Parvulustat is even more stable than Tendamistat. Furthermore, investigations on three C-terminally truncated Parvulustat derivatives indicate that the higher stability is caused by the long flexible C-terminus.     

Substrate-inhibitor interactions in the kinetics of alpha-amylase inhibition by ragi alpha-amylase/trypsin inhibitor (RATI) and its various N-terminal fragments

The ragi alpha-amylase/trypsin bifunctional inhibitor (RATI) from Indian finger millet, Ragi (Eleucine coracana Gaertneri), represents a new class of cereal inhibitor family. It exhibits a completely new motif of trypsin inhibitory site and is not found in any known trypsin inhibitor structures. The alpha-amylase inhibitory site resides at the N-terminal region. These two sites are independent of each other and the inhibitor forms a ternary (1:1:1) complex with trypsin and alpha-amylase. The trypsin inhibition follows a simple competitive inhibition obeying the canonical serine protease inhibitor mechanism. However, the alpha-amylase inhibition kinetics is a complex one if larger (> or =7 glucose units) substrate is used. While a complete inhibition of trypsin activity can be achieved, the inhibition of amylase is not complete even at very high molar concentration. We have isolated the N-terminal fragment (10 amino acids long) by CNBr hydrolysis of RATI. This fragment shows a simple competitive inhibition of alpha-amylase activity. We have also synthesized various peptides homologous to the N-terminal sequence of RATI. These peptides also show a normal competitive inhibition of alpha-amylase with varying potencies. It has also been shown that RATI binds to the larger substrates of alpha-amylase. In light of these observations, we have reexamined the binding of proteinaceous inhibitors to alpha-amylase and its implications on the mechanism and kinetics of inhibition.     

Amide proton exchange in the alpha-amylase polypeptide inhibitor Tendamistat studied by two-dimensional 1H nuclear magnetic resonance

The individual amide proton exchange rates in Tendamistat at pH 3.0 and 50 degrees C were measured by using two-dimensional 1H nuclear magnetic resonance. Overall, it was found that the distribution of exchange rates along the sequence is dominated by the interstrand hydrogen bonds of the beta-sheet structures. The slowly exchanging protons in the core of the two beta-sheets were shown to exchange via an EX2 mechanism. Further analysis of the data indicates that different large-scale structure fluctuations are responsible for the exchange from the two beta-sheets, even though the three-dimensional structure of Tendamistat appears to consist of a single structural domain.     

Inhibition of growth of Aspergillus flavus and fungal alpha-amylases by a lectin-like protein from Lablab purpureus

Aspergillus flavus is a fungal pathogen of maize causing an important ear rot disease when plants are exposed to drought and heat stress. Associated with the disease is the production of aflatoxins, which are a series of structurally related mycotoxins known to be carcinogenic. Previous research has suggested that the alpha-amylase of A. flavus promotes aflatoxin production in the endosperm of infected maize kernels. We report here the isolation and characterization of a 36-kDa alpha-amylase inhibitor from Lablab purpureus (AILP). AILP inhibited the alpha-amylases from several fungi but had little effect on those from animal and plant sources. The protein inhibited conidial germination and hyphal growth of A. flavus. The amino acid sequence indicated that AILP is similar to lectin members of a lectin-arcelin-alpha-amylase inhibitor family described in common bean and shown to be a component of plant resistance to insect pests. AILP also agglutinated papain-treated red blood cells from human and rabbit. These data indicate that AILP represents a novel variant in the lectin-arcelin-alpha-amylase inhibitor family of proteins having lectin-like and alpha-amylase inhibitory activity.     

Rice bifunctional alpha-amylase/subtilisin inhibitor: cloning and characterization of the recombinant inhibitor expressed in Escherichia coli

The complete nucleotide sequences of the cDNA and its gene that encode a bifunctional alpha-amylase/subtilisin inhibitor of rice (Oryza sativa L.) (RASI) were analyzed. RASI cDNA (939 bp) encoded a 200-residue polypeptide with a molecular mass of 21,417 Da, including a signal peptide of 22 amino acids. Sequence comparison and phylogenetic analysis showed that RASI is closely related to alpha-amylase/subtilisin inhibitors from barley and wheat. RASI was found to be expressed only in seeds, suggesting that it has a seed-specific function. A coding region of RASI cDNA without the signal peptide was introduced into Escherichia coli and was expressed as a His-tagged protein. Recombinant RASI was purified to homogeneity in a single step by Ni-chelating affinity column chromatography and characterized to elucidate the target enzyme. The recombinant inhibitor had strong inhibitory activity toward subtilisin, with an equimolar relationship, comparable with that of native RASI, and weak inhibitory activity toward some microbial alpha-amylases, but not toward animal or insect alpha-amylases. These results suggest that RASI might function in the defense of the seed against microorganisms.     

Identification of essential amino acid residues of an alpha-amylase inhibitor from Phaseolus vulgaris white kidney beans.

Kidney bean (Phaseolus vulgaris) alpha-amylase inhibitors, which are bivalent inhibitors with the subunit stoichiometry of (alphabeta)(2) complex, have been inferred to contain unique arginine, tryptophan, and tyrosine residues essential for the inhibitory activity. To test the validity of this inference, an attempt was made to identify the essential amino acid residues of a white kidney bean (P. vulgaris) alpha-amylase inhibitor (PHA-I) by using the chemical modification technique combined with amino acid sequencing and mass spectrometry. Exhaustive modification of the arginine residues by phenylglyoxal did not lead to a marked loss of activity, suggesting that no arginine residue is directly associated with the inhibitory activity. N-Bromosuccinimide treatment of PHA-I in the presence or absence of a substrate alpha-amylase revealed the involvement of two tryptophan residues in alpha-amylase inhibition, and they were identified as Trp188 of the beta-subunit by amino acid sequencing and mass spectrometry of lysylendopeptidase peptides. Further, two tyrosine residues were preferentially modified either by N-acetylimidazole or by tetranitromethane, resulting in a concomitant loss of most of the PHA-I activity. Amino acid sequencing of the lysylendopeptidase peptides from a tetranitromethane-modified PHA-I identified Tyr186 of the beta-subunit as an essential residue.