Cloning and Expression of a Schwanniomyces occidentalis alpha-Amylase Gene in Saccharomyces cerevisiae

An alpha-amylase gene (AMY) was cloned from Schwanniomyces occidentalis CCRC 21164 into Saccharomyces cerevisiae AH22 by inserting Sau3AI-generated DNA fragments into the BamHI site of YEp16. The 5-kilobase insert was shown to direct the synthesis of alpha-amylase. After subclones containing various lengths of restricted fragments were screened, a 3.4-kilobase fragment of the donor strain DNA was found to be sufficient for alpha-amylase synthesis. The concentration of alpha-amylase in culture broth produced by the S. cerevisiae transformants was about 1.5 times higher than that of the gene donor strain. The secreted alpha-amylase was shown to be indistinguishable from that of Schwanniomyces occidentalis on the basis of molecular weight and enzyme properties.     

Analysis of the alpha-amylase gene of Schwanniomyces occidentalis and the secretion of its gene product in transformants of different yeast genera

We have cloned and characterized the alpha-amylase gene (AMY1) of the yeast Schwanniomyces occidentalis. A cosmid gene library of S. occidentalis DNA was screened in Saccharomyces cerevisiae for alpha-amylase secretion. The positive clone contained a DNA fragment harbouring an open reading frame of 1536 nucleotides coding for a 512-amino-acid polypeptide with a calculated Mr of 56,500. The deduced amino acid sequence reveals significant similarity to the sequence of the Saccharomycopsis fibuligera and Aspergillus oryzae alpha-amylases. The AMY l gene was found to be expressed from its original promoter in S. cerevisiae, Kluyveromyces lactis and Schizo-saccharomyces pombe leading to an active secreted gene product and thus enabling the different yeast transformants to grow on starch as a sole carbon source.     

Molecular cloning, nucleotide sequencing, and expression of the Bacillus subtilis (natto) IAM1212 alpha-amylase gene, which encodes an alpha-amylase structurally similar to but enzymatically distinct from that of B. subtilis 2633.

An alpha-amylase gene of Bacillus subtilis (natto) IAM1212 was cloned in a lambda EMBL3 bacteriophage vector, and the nucleotide sequence was determined. An open reading frame encoding the alpha-amylase (AMY1212) consists of 1,431 base pairs and contains 477 amino acid residues, which is the same in size as the alpha-amylase (AMY2633) of B. subtilis 2633, an alpha-amylase-hyperproducing strain, and smaller than that of B. subtilis 168, Marburg strain. The amino acid sequence of AMY1212 is different from that of AMY2633 at five residues. Enzymatic properties of these two alpha-amylases were examined by introducing the cloned genes into an alpha-amylase-deficient strain, B. subtilis M15. It was revealed that products of soluble starch hydrolyzed by AMY1212 are maltose and maltotriose, while those of AMY2633 are glucose and maltose. From the detailed analyses with oligosaccharides as substrates, it was concluded that the difference in hydrolysis products of the two similar alpha-amylases should be ascribed to the different activity hydrolyzing low-molecular-weight substrates, especially maltotriose; AMY1212 slowly hydrolyzes maltotetraose and cannot hydrolyze maltotriose, while AMY2633 efficiently hydrolyzes maltotetraose and maltotriose. Further analyses with chimeric alpha-amylase molecules constructed from the cloned genes revealed that only one amino acid substitution is responsible for the differences in hydrolysis products.     

The nucleotide sequence of an α-amylase gene from an alkalopsychrotrophic Micrococcus sp

An alpha-amylase gene from Micrococcus sp. 207 was cloned into Escherichia coli JM101 using the vector pHSG399. The constructed recombinant plasmid pYK63 contained a 4.8 kb chromosomal DNA fragment derived from strain 207 DNA. The cloned amylase isolated from E. coli JM101 (pYK63) produced mainly maltotetraose from starch, and exhibited temperature and pH activity profiles closely similar to those of the enzyme from the original strain. Nucleotide sequence analysis of the cloned DNA fragment revealed one open reading frame containing the gene which consisted of 3312 bp (1104 amino acids). When compared with several other alpha-amylases, three consensus sequences were identified in the region of the active site. About 300 amino acid residues were present both upstream and downstream of the active site region.     

alpha-Amylase of Clostridium thermosulfurogenes EM1: nucleotide sequence of the gene, processing of the enzyme, and comparison of other alpha-amylases

The nucleotide sequence of the alpha-amylase gene (amyA) from Clostridium thermosulfurogenes EM1 cloned in Escherichia coli was determined. The reading frame of the gene consisted of 2,121 bp. Comparison of the DNA sequence data with the amino acid sequence of the N terminus of the purified secreted protein of C. thermosulfurogenes EM1 suggested that the alpha-amylase is translated from mRNA as a secretory precursor with a signal peptide of 27 amino acid residues. The deduced amino acid sequence of the mature alpha-amylase contained 679 residues, resulting in a protein with a molecular mass of 75,112 Da. In E. coli the enzyme was transported to the periplasmic space and the signal peptide was cleaved at exactly the same site between two alanine residues. Comparison of the amino acid sequence of the C. thermosulfurogenes EM1 alpha-amylase with those from other bacterial and eucaryotic alpha-amylases showed several homologous regions, probably in the enzymatically functioning regions. The tentative Ca(2+)-binding site (consensus region I) of this Ca(2+)-independent enzyme showed only limited homology. The deduced amino acid sequence of a second obviously truncated open reading frame showed significant homology to the malG gene product of E. coli. Comparison of the alpha-amylase gene region of C. thermosulfurogenes EM1 (DSM3896) with the beta-amylase gene region of C. thermosulfurogenes (ATCC 33743) indicated that both genes have been exchanged with each other at identical sites in the chromosomes of these strains.     

Cloning and characterization of a third type of human alpha-amylase gene, AMY2B

We have previously reported concerning the existence of a third type of human alpha-amylase gene, AMY3 [Emi et al., Gene 62 (1988) 229-235; Tomita et al., Gene 76 (1989) 11-18], which is expressed in a lung carcinoid tissue, and differs in nucleotide sequence from the two previously characterized human alpha-amylase genes coding for salivary and pancreatic isozymes, termed AMY1 and AMY2, respectively. Here, we rename this gene AMY2B to coincide with the designation by Gumucio et al. [Mol. Cell Biol. 8 (1988) 1197-1205] and describe its genetic properties as revealed by sequencing studies. It consists of ten major exons whose sequences are highly homologous to those of AMY1 and AMY2. Not only the exons, but also most of the introns seem to be highly conserved, as judged from physical mapping data. The AMY2B gene identified from mRNA in a lung carcinoid tissue has at least two additional untranslated exons in its 5' region; hence the promoter lies far upstream relative to the other two AMY genes.     

Barley alpha-amylase/subtilisin inhibitor: structure, biophysics and protein engineering

Bifunctional alpha-amylase/subtilisin inhibitors have been implicated in plant defence and regulation of endogenous alpha-amylase action. The barley alpha-amylase/subtilisin inhibitor (BASI) inhibits the barley alpha-amylase 2 (AMY2) and subtilisin-type serine proteases. BASI belongs to the Kunitz-type trypsin inhibitor family of the beta-trefoil fold proteins. Diverse approaches including site-directed mutagenesis, hybrid constructions, and crystallography have been used to characterise the structures and contact residues in the AMY2/BASI complex. The three-dimensional structure of the AMY2/BASI complex is characterised by a completely hydrated Ca2+ situated at the protein interface that connects the three catalytic carboxyl groups in AMY2 with side chains in BASI via water molecules. Using surface plasmon resonance (SPR) and isothermal titration calorimetry (ITC), we have recently demonstrated Ca2+-modulated kinetics of the AMY2/BASI interaction and found that the complex formation involves minimal structural changes. The modulation of the interaction by calcium ions makes it unique among the currently known binding mechanisms of proteinaceous alpha-amylase inhibitors.     

Genetic coadaptation of the amylase gene system in Drosophila melanogaster: evidence for the selective advantage of the lowest AMY activity and of its epistatic genetic background

In natural populations of Drosophila melanogaster, an amylase isozyme with the lowest alpha-amylase activity (AMY(1,1)) is predominant. To evaluate the selective significance of AMY(1,1) and its regulatory factor(s), we examined selection experiments in laboratory populations on two distinct food environments. After 300 generations, AMY(1,1) became predominant (89%) in a glucose (a product of AMY)-rich environment, while an isozyme with higher alpha-amylase activity, AMY(1,6), became predominant (83%) in a starch (substrate)-rich environment. We found that the identical alleles of the amylase (Amy) gene, which encodes each of AMY(1,1) and AMY(1,6), were shared between the two populations in the different food environments, employing the nucleotide sequencing of the duplicated Amy genes. Nevertheless, AMY(1,6) homozygotes selected in the starch-rich environment had a twofold higher AMY enzyme activity than those selected in the glucose-rich environment, suggesting a coadaptation of the coding region and its regulatory factor(s) on the genetic background. Such a difference in AMY enzyme activity was not detected between AMY(1,1) homozygotes, suggesting that the effect of the genetic background is epistatic. Our results indicate that natural selection is working on the Amy gene system as a whole for flies to adapt to the various food environments of local populations.     

Mutational analysis of target enzyme recognition of the beta-trefoil fold barley alpha-amylase/subtilisin inhibitor

The barley alpha-amylase/subtilisin inhibitor (BASI) inhibits alpha-amylase 2 (AMY2) with subnanomolar affinity. The contribution of selected side chains of BASI to this high affinity is discerned in this study, and binding to other targets is investigated. Seven BASI residues along the AMY2-BASI interface and four residues in the putative protease-binding loop on the opposite side of the inhibitor were mutated. A total of 15 variants were compared with the wild type by monitoring the alpha-amylase and protease inhibitory activities using Blue Starch and azoalbumin, respectively, and the kinetics of binding to target enzymes by surface plasmon resonance. Generally, the mutations had little effect on k(on), whereas the k(off) values were increased up to 67-fold. The effects on the inhibitory activity, however, were far more pronounced, and the K(i) values of some mutants on the AMY2-binding side increased 2-3 orders of magnitude, whereas mutations on the other side of the inhibitor had virtually no effect. The mutants K140L, D150N, and E168T lost inhibitory activity, revealing the pivotal role of charge interactions for BASI activity on AMY2. A fully hydrated Ca(2+) at the AMY2-BASI interface mediates contacts to the catalytic residues of AMY2. Mutations involving residues contacting the solvent ligands of this Ca(2+) had weaker affinity for AMY2 and reduced sensitivity to the Ca(2+) modulation of the affinity. These results suggest that the Ca(2+) and its solvation sphere are integral components of the AMY2-BASI complex, thus illuminating a novel mode of inhibition and a novel role for calcium in relation to glycoside hydrolases.     

alpha-Amylase of Clostridium thermosulfurogenes EM1: nucleotide sequence of the gene, processing of the enzyme, and comparison of other alpha-amylases.

The nucleotide sequence of the alpha-amylase gene (amyA) from Clostridium thermosulfurogenes EM1 cloned in Escherichia coli was determined. The reading frame of the gene consisted of 2,121 bp. Comparison of the DNA sequence data with the amino acid sequence of the N terminus of the purified secreted protein of C. thermosulfurogenes EM1 suggested that the alpha-amylase is translated from mRNA as a secretory precursor with a signal peptide of 27 amino acid residues. The deduced amino acid sequence of the mature alpha-amylase contained 679 residues, resulting in a protein with a molecular mass of 75,112 Da. In E. coli the enzyme was transported to the periplasmic space and the signal peptide was cleaved at exactly the same site between two alanine residues. Comparison of the amino acid sequence of the C. thermosulfurogenes EM1 alpha-amylase with those from other bacterial and eucaryotic alpha-amylases showed several homologous regions, probably in the enzymatically functioning regions. The tentative Ca(2+)-binding site (consensus region I) of this Ca(2+)-independent enzyme showed only limited homology. The deduced amino acid sequence of a second obviously truncated open reading frame showed significant homology to the malG gene product of E. coli. Comparison of the alpha-amylase gene region of C. thermosulfurogenes EM1 (DSM3896) with the beta-amylase gene region of C. thermosulfurogenes (ATCC 33743) indicated that both genes have been exchanged with each other at identical sites in the chromosomes of these strains.     

Ovine alpha-amylase genes: isolation, linkage mapping and association analysis with milk traits

On the basis of comparisons between cattle and sheep genome mapping information the ovine alpha-amylase gene was examined as a possible genetic marker for milk traits in sheep. The objective of the present study was to isolate, map and determine whether this gene is a candidate gene for milk traits. DNA fragments (832 and 2360 bp) corresponding to two different AMY genes were isolated, and one SNP in intron 3 and one GTG deletion in exon 3 of the 2360 bp DNA fragment were found. The 2360 bp ovine AMY DNA fragment was located on chromosome 1 by linkage mapping using the International Mapping Flock. No association was found between estimated breeding values for milk yield, protein and fat contents and AMY genotypes in a daughter design comprising 13 Manchega families with an average of 29 daughters (12-62) per sire.     

Cloning and expression of a Clostridium acetobutylicumα-amylase gene in Escherichia coli

A gene library of Clostridium acetobutylicum ATCC824 was constructed in the plasmid vector pEcoR251. The library was tested for the presence of starch hydrolyzing clones. One clone in which the recombinant plasmid, pVP101, conferred alpha-amylase activity to the Escherichia coli host cell, was detected. The gene is carried on a 3.45-kbp BglII restriction fragment. A detailed physical map of pVP101 is presented.     

In vitro colonization ability of human colon mucosa by exogenous Lactobacillus strains

Abstract A 5.4 kb Hind III DNA fragment carrying the gene encoding raw starch-digesting α-amylase (RSDA), has been previously cloned from Bacillus circulans F-2 and expressed in Escherichia coli [Kim et al. (1990) Biochim. Biophys. Acta 1048, 2233–2238]. Interestingly, when the cell extract of E. coli harboring a plasmid carrying this fragment was incubated with l M NaCl, it exhibited about 10 times higher enzyme activity than when assayed without NaCl. Differential zymograms showed two different amylase activities: one for RSDA and the other for a salt-dependent a-amylase (SDA). Even though RSDA activity was detected without NaCl, SDA activity was detected only in high concentrations of NaCl. SDA activity was fully detected at above l M NaCl. Results from subcloning of the genes, fractionation analysis of cell extracts, and immunological assays clearly suggested that the two amylases are genetically distinct and that genes for both enzymes are closely linked on the 5.4 kb DNA fragment.     

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.     

The amino acid sequence of pancreatic alpha-amylase from the ostrich, Struthio camelus

The amino-acid sequence of alpha-amylase isolated from the pancreas of the ostrich, Struthio camelus was determined. The alpha-amylase (OPA) consisted of 497 amino acid residues with pyroglutamic acid at the N-terminus and no oligosaccharide. Amino acid identity between OPA and chicken, porcine and human pancreatic alpha-amylases individually, was found to be 88, 82 and 86%, respectively.     

Detection of human urinary alpha-amylase encoded by the AMY2B gene using a fluorogenic substrate, FG5P.

The existence of alpha-amylase (HXA) encoded by alpha-amylase gene AMY2B in healthy humans was examined using a fluorogenic substrate, FG5P (FG-G-G-G-G-P: FG, 6-deoxy-6-[(2-pyridyl)amino]-D-glucose residue; G, glucose residue; P, p-nitrophenyl residue; -, alpha-1,4-glycosidic bond). Chromatofocusing of urine from a healthy human was carried out. FG5P was digested with the fractions exhibiting alpha-amylase activity and each digest at an early stage was analyzed by HPLC. FG5P was hydrolyzed to FG3 (FG-G-G) and p-nitrophenyl alpha-maltoside (G-G-P), and to FG4 (FG-G-G-G) and p-nitrophenyl alpha-glucoside (G-P). The molar ratios of FG4 to FG3 (FG4/FG3) in the digests with basic fractions were larger than those in the digests of human pancreatic alpha-amylase (HPA, 1.11) and human salivary alpha-amylase (HSA, 0.51). Considering that the value for the AMY2B gene product with yeast (yHXA) is 1.88, a value of more than 1.11 implies that HXA exists. The amount of HXA was determined after removal of HSA on an anti-human salivary alpha-amylase antibody bound column. The FG4/FG3 values for six urine samples free from HSA were 1.23-1.26. Assuming that the FG4/FG3 value for HXA is the same as that for yHXA, the ratios of HXA and HPA were estimated to be 1:5.4-4.1. The results obtained showed that the AMY2B gene is usually expressed as HXA in healthy humans.     

A natural variant of Bacillus licheniformis alpha-amylase isolated from flour mill wastewaters sheds light on the origin of high thermostability

AIMS: Understanding the origin of high thermostability exhibited by the alpha-amylase produced by a natural strain of Bacillus licheniformis. METHODS AND RESULTS: The MSH320 alpha-amylase gene has been cloned from a native strain of B. licheniformis isolated from flour mill wastewaters in Kashan, central Iran, and its nucleotide sequence was determined (GenBank Accession Number AF438149). Whereas previously cloned B. licheniformisalpha-amylase (BLA) genes are nearly identical, the MSH320 gene coding sequence presents only 93% identity with the reference 'wild-type' BLA gene, most of the nucleotide changes leading to silent mutations. Amino acid substitutions occurred at 19 of the 483 residues of the matured protein, distributed all along the protein sequence. Nevertheless, the natural BLA variant presents thermoinactivation kinetics similar to that of the reference BLA. Protein modelling and structural predictions at the substitution sites suggest that half of the mutations may have a significant stabilizing or destabilizing effect on the protein structure. Compensatory mutations thus occurred in the natural variant in order to maintain thermostability to the level of the reference enzyme. CONCLUSIONS: The exceptional high thermostability of BLA, although produced by a nonthermophilic organism, is not fortuitous but subject to a selective pressure still at work in natural environments. SIGNIFICANCE AND IMPACT OF THE STUDY: BLA thermal performances are not naturally maximized and can be substantially improved by protein engineering.