Acid-stable α-Amylase of Black Aspergilli

Some general properties of the acid-stable dextrinizing amylase of black Aspergillus were investigated comparing with those of Taka-amylase A. The mode of action on starch of this amylase was quite similar to that of Taka-amylase A. Saccharifying degree at red point in starch-iodine color reaction was 5.1% and the limit of starch saccharification was a little over 40 per cent calculated as glucose with both amylases. Maltase activity was absent. Degradation products in the course of starch hydrolysis were also quite similar and they mutarotated downward. So this amylase was decided to be α-type. Thermal stability of the acid-stable α-amylase was higher than that of Taka-amylase A. Its acid stability was much higher than that of Taka-amylase A. Taka-amylase A was inactivated completely at pH 2.2, 37°C, for 30 min, but the acid-stable α-amylase retained 87% of its original activity.

From the amylase preparation of black Aspergillus acid-stable α-amylase and acidunstable α-amylase were separated by gel filtration on sephadex G-100 column. From the acid-unstable α-amylase fraction this enzyme was purified by fractionations with rivanol and acetone, and finally obtained as a homogeneous protein after gel filtration with sephadex G-50. Comparison of some general properties between the two α-amylases was carried out. Catalytic action was quite similar with both enzymes, but dextrinizing unit per mg enzyme protein of the acid-unstable α-amylase was about 5.6 times as large as that of the acid-stable α-amylase. The acid-unstable α-amylase was less heat-stable than the acid-stable α-amylase. Acid stability and pH-activity curve were compared with both α-amylases. High stability of the acid-stable α-amylase in acidic condition was observed, but, in alkaline range, it was more sensitive than the acid-unstable α-amylase.     

Acid-stable α-Amylase of Black Aspergilli

When black Aspergilli were cultivated in appropriate condition, culture filtrate showed dextrinizing activity even after acid treatment such as pH 2.5, at 37°C for 30 minutes. It suggested the existence of acid-stable dextrinizing amylase. To isolate this enzyme paper el-ectrophoretic procedure was carried out and the spot which showed acid-stable dextrinizing activity was obtained in addition to α-amylase and glucoamylase spots. This new amylase was purified by fractional precipitation with ammonium sulfate, rivanol and acetone, and was obtained in a crystalline form.     

Acid-stable α-Amylase of Black Aspergilli

The amino acid compositions of the acid-stable α-amylase and the acid-unstable α-amylase obtained from Aspergillus niger were determined by automatic column chromatography. The amino acid composition of the acid-unstable α-amylase was very similar to that of the α-amylase of Aspergillus oryzae. The amino acid composition of the acid-stable α-amylase was also similar in most part, but differed from that of the acid-unstable α-amylase in the following features, (a) The lysine content was lower, (b) Although the totals of carboxyl and amide were almost equal, there were considerably more free carboxyl residues, (c) The serine content was higher, (d) The proline content was lower. These facts may be related to the lower isoelectric point (pH 3.44) of the acid-stable α-amylase.

Amino-terminal amino acid analysis demonstrated one mole of amino-terminal leucine or isoleucine per mole of the acid-stable α-amylase and one mole of amino-terminal alanine per mole of the acid-unstable α-amylase.     

Acid-Stable α-Amylase of Black Aspergilli

The acid-stable α-amylase or the acid-unstable α-amylase from Aspergillus niger contained 24 moles or 7 moles mannose and 4 moles or 1 mole hexosamine per mole of protein, respectively.

The acid-stable α-amylase and the acid-unstable α-amylase contained calcium only, but not detectable amounts of other metals. Calcium contents of the both enzymes were converged to at least one gram atom per mole of enzyme by dialysis against acetate buffer. The last calcium could be removed under the suitable conditions by EDTA. Calcium removal by EDTA was accompanied by the loss of activity and by the little change of UV absorption spectra. The phenomenon caused by calcium removal were partially reversible. This last one atom of calcium seemed to be essential for the maintenance of active structure of α-amylase.     

Chemical Modification of Amino Groups of Acid-stable α-Amylase and Acid-unstable α-Amylase from Aspergillus niger

Monochlorotrifluoro-p-benzoquinone (CFQ) was used for investigating the state of the amino groups of acid-stable α-amylase and acid-unstable α-amylase. About half of the total amino groups in both enzyme molecules were reacted with the reagent. The unreactive amino groups seemed to exist in a different state from the reactive ones. Both enzymes whose amino groups were modified by CFQ still maintained the α-phenylmaltosidase activity in spite of losing or decreasing the amylase activity. These facts suggest that the amino groups of both enzymes were not in the active site but the modification of them caused steric hindrance.

The pH-stability of the acid-unstable α-amylase whose one or two amino groups were modified with succinic anhydride or 2,4,6-trinitrobenzene-l-sulfonate (TNBS) increased on the acidic side and decreased on the alkaline side, but further modification of them led to decrease the stability on both sides.     

Engineering of Barley α-Amylase

Abstract

Protein engineering of barley α-amylase addressed the roles of Ca²⁺ in activity and inhibition by barley α-amylase/subtilisin inhibitor (BASI), multiple attach in polysaccharide hydrolysis, secondary starch binding sites, and BASI hot spots in AMY2 recognition. AMY1/AMY2 isozyme chimeras faciliatated assignment of function to specific regions of the structure. An AMY1 fusion with starch binding domain and AMY1 mutants in the substrate binding cleft gave degree of multiple attack of 0.9–3.3, compared to 1.9 for wild-type. About 40% of the secondary attacks, succeeding the initial endo-attack, produced DP5-10 maltooligosaccharides in similar proportion for all enzyme variants, whereas shorter products, comprising about 25%, varied depending on the mutation. Secondary binding sites were important in both multiple attack and starch granule hydrolysis. Surface plasmon resonance and inhibition analyses indicated the importance of fully hydrated Ca²⁺ at the AMY2/BASI interface to strengthen the complex. Engineering of intermolecular contacts in BASI modulated the affinity for AMY2 and the target enzyme specificity.     

Formation of Complex of Proteinous Animal α-Amylase Inhibitor (Haim) with Hog Pancreatic α-Amylase

A limited proteolysis of Avicel-adsorbable, Avicel-disintegrating endocellulase I (molecular weight 130,000) from Geotrichum candidum with subtilisin yielded a protein (molecular weight 80,000) which proved fully active toward soluble substrates such as CM-cellulose, but lost both the abilities to be adsorbed onto insoluble substrates and to disintegrate the cellulose fibres. An immunological experiment showed precipitin lines between endocellulase I and subtilisin-modified endocellulase in the pattern of partial identity. N-Bromosuccinimide-oxidized endocellulase I lost cellulase activity, but retained its adsorbability onto Avicel. It is suggested that endocellulase I had both the affinity site for adsorbing onto insoluble substrates and the ordinary active site.     

Reversibility of Acid-Inactivation of Bacillus subtilis’ α-Amylase

The inactivation of Bacillus subtilis’ α-amylase by acid was shown to be reversible. In the experiment, two different Bac. subtilis’ α-amylases, saccharifying and liquefying types, were used and the reversibility was investigated deviding into two processes of inactivation and reactivation. Both amylases showed the reversibility in a similar degree and in general the inactivated enzymes by acid were reactivated only by adjusting the pH to slightly alkaline values followed by incubation under certain conditions. However, the reversibility, especially, the reactivation was greatly influenced by several chemicals, the effect of certain chemicals being different according to the type of the bacterial amylase. Contrary to liquefying amylase, saccharifying amylase was insensitive to metal chelators but, nevertheless, the reactivation of the amylase was prevented by metal chelators. Also the reactivation of saccharifying amylase was inhibited by sulfhydryl reagents, although the native enzyme was quite insensitive to the chemicals. In the acid-inactivation and reactivation process, a reversible change in the ultraviolet absorption spectra of the enzymes was observed, and some discussion of the implication was presented.     

Reversibility of Heat-Inactivation of Bacillus subtilis’ α-Amylase

Inactivation of Bacillus subtilis’ α-amylase by heat was found to be reversible under a certain condition, and the factors affecting there were investigated, distinguishing into two groups: those influencing on the inactivation process by heat and those on the reactivation at the subsequent incubation after heating. Generally, the amylase heated in borate buffer solution was best in the reactivation degree. For reactivation of the heat-inactivated enzyme there was found an optimum in temperature, pH and concentration of enzyme, respectively. The reactivation was temporarily prevented by urea, but irreversibly inhibited by either calcium salts or calcium binding agents. In the reversible heat-inactivation of the enzyme was also found a reversible change in the absorption spectra as well as in the behavior of the enzyme toward proteinase.     

The Inhibition of α-Amylase by Tea Polyphenols

The inhibition of α-amylase from human saliva by polyphenolic components of tea and its specificity was investigated in vitro. Four kinds of green tea catechins, and their isomers and four kinds of their dimeric compounds (theaflavins) produced oxidatively during black tea production were isolated. They were (?)-epicatechin (EC), (?)-epigallocatechin (EGC), (?)-epicatechin gallate (ECg), (?)-epigallocatechin gallate (EGCg), (?)-catechin (C), (?)-gallocatechin (GC), (?)-catechin gallate (Cg), (?)-gallocatechin gallate (GCg), theaflavin (TF1), theaflavin monogallates (TF2A and TF2B), and theaflavin digallate (TF3). Among the samples tested, EC, EGC, and their isomers did not have significant effects on the activity of α-amylase. All the other samples were potent inhibitors and the inhibitory effects were in the order of TF3>TF2A>TF2B>TFl>Cg> GCg > ECg > EGCg. The inhibitory patterns were noncompetitive except for TF3.     

Evolutionary History of Eukaryotic α-Glucosidases from the α-Amylase Family

Although some α-glucosidases from the α-amylase family (glycoside hydrolase family GH13) have been studied extensively, their exact number, organization on the chromosome, and orthology/paralogy relationship were unknown. This was true even for important disease vectors where gut α-glucosidase is known to be receptor for the Bin toxin used to control the population of some mosquito species. In some cases orthologs from related species were studied intensively, while potentially important paralogs were omitted. We have, therefore, used a bioinformatics approach to identify all family GH13 α-glucosidases from the selected species from Metazoa (including three mosquito species: Aedes aegypti, Anopheles gambiae, and Culex quinquefasciatus) as well as from Fungi in an effort to characterize their arrangement on the chromosome and evolutionary relationships among orthologs and among paralogs. We also searched for pseudogenes and genes coding for enzymatically inactive proteins with a possible new function. We have found GH13 α-glucosidases mostly in Arthropoda and Fungi where they form gene families, as a result of multiple lineage-specific gene duplications. In mosquito species we have identified 14 α-glucosidase (Aglu) genes of which only five have been biochemically characterized so far, two are putative pseudogenes and the rest remains uncharacterized. We also revealed quite a complex evolutionary history of the eukaryotic α-glucosidases probably involving multiple losses of genes or horizontal gene transfer from bacteria.     

Stepwise Introduction of Regulatory Genes Stimulating Production of α-Amylase into Bacillus subtilis : Construction of an α-Amylase Extrahyper Producing Strain

The production of extracellular α-amylase in Bacillus subtilis is probably regulated by many genetic elements, such as amyR, tmrA7, pap, amyB and sacU. Additional genetic elements, C-108 and A-2 for production of the α-amylase were found in D-cycloserine and ampicillin resistant mutants (C108 and A2) of B. subtilis 6160, respectively. Strain C108 increased the production of α-amylase about 5 times and protease about 80 times compared to parental 6160 strain. Strain A2 showed a nearly 6-fold increased α-amylase production.

These genetic elements displayed a synergistic effect with other genetic factors in production of extracellular α-amylase when these elements were transferred by DNA mediated transformation. By stepwise introduction of these and other genetic elements into B. subtilis 6160 by transformation and mutation, strains with higher α-amylase producing activity were obtained. The finally obtained strain, T2N26, produced about 1,500-2,000 times more α-amylase than parental 6160 strain.     

Inhibition of Early Steps in the Gibberellin-Activated Synthesis of α-Amylase

Subsequent production of amylase is severely inhibited if barban [4-chloro-2-butynyl N-(3-chlorophenyl) carbamate] is added to embryo-free half seeds of barley within 4 to 5 hours after gibberellic acid treatment of these seeds. Thirty to 50 mg/L concentrations of barban are effective. Barban inhibition is non-competitive with respect to gibberellic acid. Addition of barban 7 hours or more after gibberellic acid treatment is almost without effect.The delay between gibberellic acid treatment and amylase formation tends to become shorter with more prolonged imbibition periods. Regardless of imbibition period, susceptibility to barban is lost within 7 hours after gibberellic acid treatment.Other herbicidally active phenylurethanes are also inhibitors, but none are as effective as barban. Phenethyl alcohol and 2 arylcarbamates can act as inhibitors.     

Acylated Flavonoids from Spiraea Genus as Inhibitors of α-Amylase

Russian Journal of Bioorganic Chemistry - Spiraea L. belongs to a genus of deciduous-leaved shrubs in the Rosaceae family that is abundant in Eastern Siberia. The study of six species of Spiraea...     

On the Inducers of α-Amylase Formation In Aspergillus oryzae

In a previous paper it has been described that α-amylase formation in Aspergillus oryzae is stimulated by soluble starch, glycogen and maltose, whereas it is inhibited by glucose, which is added into a growing medium or a secondary incubation medium as the carbon source. The present paper reports that isomaltose and panose are the most effective inducers among a large number of sugars examined here, and suggests the importance of transglucosidase action demonstrated in view of α-amylase formation. The initial action of inducers in this system is also discussed.     

Isolation of a Raw Starch-Binding Fragment from Barley α-Amylase

Barley α-amylase was purified by ammonium sulfate fraction, ion-exchange, ultrafiltration, and gel filtration to homogeneity. The purified enzyme was partially digested with trypsin, and the reaction mixture was applied to a cyclohepta-amylose epoxy Sepharose 6B column. Bound fragments were eluted by free cyclohepta-amylose, lyophilized, and separated on Tricine gels. Four fragments were shown to interact with β-cyclodextrin. The fragment that could be identified on the gel with the lowest molecular weight (11 kDa) was electroblotted onto PVDF membrane for sequencing. The N-terminal sequence of this fragment was determined with the N-terminal amino acid corresponding to Ala283 in the whole protein. The trypsin cleavage was at Lys282/Ala283 and the C-terminal cleavage occurred at Lys354/Ile355 to give a fragment size of 11 kDa as estimated by SDS-PAGE. The fragment would be located at the C-terminal region, forming a majority of the antiparallel β-sheets in domain C and the α₇-and α₈-helices of the (α/β)₈ domain.