Nucleotide sequence of the amylase gene from Bacillus subtilis

Characterization of the Butyrivibrio fibrisolvens glgB gene, which encodes a glycogen-branching enzyme with starch-clearing activity

A Butyrivibrio fibrisolvens H17c glgB gene, was isolated by direct selection for colonies that produced clearing on starch azure plates. The gene was expressed in Escherichia coli from its own promoter. The glgB gene consisted of an open reading frame of 1,920 bp encoding a protein of 639 amino acids (calculated Mr, 73,875) with 46 to 50% sequence homology with other branching enzymes. A limited region of 12 amino acids showed sequence similarity to amylases and glucanotransferases. The B. fibrisolvens branching enzyme was not able to hydrolyze starch but stimulated phosphorylase alpha-mediated incorporation of glucose into alpha-1,4-glucan polymer 13.4-fold. The branching enzyme was purified to homogeneity by a simple two-step procedure; N-terminal sequence and amino acid composition determinations confirmed the deduced translational start and amino acid sequence of the open reading frame. The enzymatic properties of the purified enzyme were investigated. The enzyme transferred chains of 5 to 10 (optimum, 7) glucose units, using amylose and amylopetin as substrates, to produce a highly branched polymer.

Genetic manipulation of Bacillus amyloliquefaciens

Application of modern gene technology to strain improvement of the industrially important bacterium Bacillus amyloliquefaciens is reported. Several different plasmid constructions carrying the alpha-amylase gene (amyE) from B. amyloliquefaciens were amplified in this species either extrachromosomally or intrachromosomally. The amyE gene cloned on a pUB110-derived high copy plasmid pKTH10 directed the highest yields both in rich laboratory medium and in crude industrial medium. The alpha-amylase activity, when compared with the parental strain, was enhanced up to 20-fold in the pKTH 10 transformant. This strain showed decreased activities for other exoenzymes, such as proteases and beta-glucanase suggesting common limiting resources in the processing of these enzymes. Deletions were made in vitro in genes encoding neutral (nprE), alkaline (aprE) protease and beta-glucanase (bglA). The engineered genes were cloned into the thermosensitive plasmid pE194, and the resulting plasmids were used to replace the corresponding wild type chromosomal genes in B. amyloliquefaciens by integration-excision at non-permissive temperature. The double mutant deficient in the major proteases (delta nprE delta aprE) showed about a 2-fold further enhancement in alpha-amylase production in the industrial medium compared with the relevant wild type background, [corrected] both when plasmid-free and when transformed with pKTH10; this strain also produced elevated levels of the chromosomally-encoded beta-glucanase; pKTH10 was stably maintained both in the wild type strain and in the delta nprE delta aprE mutant. We suggest that the higher yields in alpha-amylase and beta-glucanase in the delta nprE delta aprE strain are primarily due to improved access to limiting resources, and that decreased proteolytic degradation may have had a secondary role in retaining the high activity obtained.

Cloning, nucleotide sequence, and enzymatic characterization of an alpha-amylase from the ruminal bacterium Butyrivibrio fibrisolvens H17c

A Butyrivibrio fibrisolvens amylase gene was cloned and expressed by using its own promoter on the recombinant plasmid pBAMY100 in Escherichia coli. The amylase gene consisted of an open reading frame of 2,931 bp encoding a protein of 976 amino acids with a calculated Mr of 106,964. In E. coli(pBAMY100), more than 86% of the active amylase was located in the periplasm, and TnphoA fusion experiments showed that the enzyme had a functional signal peptide. The B. fibrisolvens amylase is a calcium metalloenzyme, and three conserved putative calcium-binding residues were identified. The amylase showed high sequence homology with other alpha-amylases in the three highly conserved regions which constitute the active centers. These and other conserved regions were located in the N-terminal half, and no similarity with any other amylase was detected in the remainder of the protein. Deletion of approximately 40% of the C-terminal portion of the amylase did not result in loss of amylolytic activity. The B. fibrisolvens amylase was identified as an endo-alpha-amylase by hydrolysis of the Phadebas amylase substrate, hydrolysis of gamma-cyclodextrin to maltotriose, maltose, and glucose and the characteristic shape of the blue value and reducing sugar curves. Maltotriose was the major initial hydrolysis product from starch, although extended incubation resulted in its hydrolysis to maltose and glucose.

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 pair of novel genes that regulate production of extracellular enzymes in Bacillus subtilis

Two novel Bacillus subtilis genes that regulate the production of several extracellular enzymes were clones and characterized. These two genes are organized as part of an operon. When cloned in a multicopy plasmid, the first gene (tenA, transcription enhancement) stimulates alkaline protease production at the transcriptional level. The second gene (tenI) exerts an opposite effect to reduce alkaline protease production. The production of neutral protease, levansucrase, and alkaline protease can be stimulated up to 11- to 55-fold. Thus, tenA is a new member of the deg (regulatory genes for degradative enzymes) family in B. subtilis. A functional degS product is required to observe the stimulatory effect from tenA. Between the promoter and the ribosome-binding site of tenA, there exists a terminatorlike structure. Deletion of this structure doubles the expression of tenA. Neither tenA nor tenI is essential for cell growth and the production of extracellular enzymes. However, inactivation of these genes causes a delay in sporulation. This operon is located close to tre on the genetic linkage map. The overall organization of this operon and its relationship with other known regulatory factors in the deg family are discussed.

Purification and characterization of the extracellular alpha-amylase from Clostridium acetobutylicum ATCC 824

The extracellular alpha-amylase (1,4-alpha-D-glucanglucanohydrolase; EC 3.2.1.1) from Clostridium acetobutylicum ATCC 824 was purified to homogeneity by anion-exchange chromatography (mono Q) and gel filtration (Superose 12). The enzyme had an isoelectric point of 4.7 and a molecular weight of 84,000, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It was a monomeric protein, the 19-amino-acid N terminus of which displayed 42% homology with the Bacillus subtilis saccharifying alpha-amylase. The amino acid composition of the enzyme showed a high number of acidic and hydrophobic residues and only one cysteine residue per mole. The activity of the alpha-amylase was not stimulated by calcium ions (or other metal ions) or inhibited by EDTA, although the enzyme contained seven calcium atoms per molecule. alpha-Amylase activity on soluble starch was optimal at pH 5.6 and 45 degrees C. The alpha-amylase was stable at an acidic pH but very sensitive to thermal inactivation. It hydrolyzed soluble starch, with a Km of 3.6 g . liter-1 and a Kcat of 122 mol of reducing sugars . s-1 . mol-1. The alpha-amylase showed greater activity with high-molecular-weight substrates than with low-molecular-weight maltooligosaccharides, hydrolyzed glycogen and pullulan slowly, but did not hydrolyze dextran or cyclodextrins. The major end products of maltohexaose degradation were glucose, maltose, and maltotriose; maltotetraose and maltopentaose were formed as intermediate products. Twenty seven percent of the glucoamylase activity generally detected in the culture supernatant of C. acetobutylicum can be attributed to the alpha-amylase.

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.

Site-directed mutagenesis of a catabolite repression operator sequence in Bacillus subtilis

Catabolite repression of the Bacillus subtilis alpha-amylase gene (amyE) involves an operator sequence located just downstream of the promoter (amyR), overlapping the transcription start site. Oligonucleotide site-directed mutagenesis of this sequence identified bases required for catabolite repression. Two mutations increased both the 2-fold symmetry of the operator and the repression ratio. Although many mutations reduced the repression ratio 3- to 11-fold, some also caused a 2-fold or greater increase in amylase production. Others caused hyperproduction without affecting catabolite repression. Homologous sequences in other catabolite-repressed B. subtilis promoters suggest a common regulatory site may be involved in catabolite repression.

Cloning and expression of raw-starch-digesting alpha-amylase gene from Bacillus circulans F-2 in Escherichia coli

The raw potato-starch-digesting alpha-amylase gene of Bacillus circulans F-2 was cloned for the first time in Escherichia coli C600, using plasmid pYEJ001. The recombinant plasmid, named pYKA3, has a 5.4 kb insert from a chromosome of the donor bacterium. Subcloning of this amylase gene gave plasmid pHA300 which carried 3.15 kb of the inserted DNA. The transformed bacterium, E. coli C600 (pYKA3), produced the amylase in the periplasmic space, whereas it is secreted outside the cell in the donor bacterium. The cloned raw-starch-digesting alpha-amylase has a molecular weight of 93,000 on SDS-PAGE, and its action pattern was absolutely the same as that of the potent raw-starch-digestible amylase produced by B. circulans F-2. The periplasmic amylase produced by the transformed E. coli (pHA300) could digest raw starch granules such as potato, corn and barley raw starch granules, indicating that the raw-starch-digesting amylase is active in E. coli. Furthermore, this amylase crossreacted with the rabbit antiserum raised against the raw potato-digesting alpha-amylase of B. circulans F-2. From these results it was concluded that the cloned amylase is the same amylase protein as B. circulans F-2 amylase, which has a potent raw-starch digestibility. Thus, this paper is to our knowledge the first describing the molecular cloning of raw-starch-digesting alpha-amylase from Bacillus species and its successful expression in E. coli.

Isolation of a cDNA encoding Aspergillus oryzae Taka-amylase A: evidence for multiple related genes

Complementary and genomic DNAs encoding Aspergillus oryzae Taka-amylase A (Taa) were cloned and sequenced. The coding sequence of the cDNA comprised the signal peptide [21 amino acids (aa)] and mature Taa (478 aa). The deduced aa sequence agrees well with the published aa sequence, except for one insertion, one deletion and ten aa substitutions. These differences might be due to the difference in the strains used. Sequence comparison of the cDNA and genomic DNA indicates the presence of eight introns ranging in size from 55 to 86 bp. Southern-blot analysis showed the presence of at least two Taa genes, and the second gene (Taa-G2) was isolated. All the intron/exon junctions follow the 'GT-AG' rule, except for intron I of the first gene (Taa-G1). The 5'-noncoding region was well conserved among the genomic genes and contained sequences similar to 'CAAT' and 'TATA' boxes at nucleotides -121 and -31, counted from the transcription start point, respectively. The 3'-noncoding regions, however, differed significantly from each other. Taa-G2 contains a sequence identical to that of several independent cDNA clones, suggesting that it may be the major transcribed gene in A. oryzae.

Sequence homology between putative raw-starch binding domains from different starch-degrading enzymes

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Genetic analysis of the promoter region of the Bacillus subtilis alpha-amylase gene

The amyR2 allele of the Bacillus subtilis alpha-amylase cis-regulatory region enhances production of amylase and transcription of amyE, the structural gene, by two- to threefold over amyR1. The amylase gene bearing each of these alleles was cloned on plasmids of about 10 to 15 copies per chromosome. Transcription of the cloned amylase gene by each amyR allele was activated at the end of exponential growth and was subject to catabolite repression by glucose. The amount of amylase produced was roughly proportional to the copy number of the plasmid, and cells containing the amyR2-bearing plasmid, pAR2, produced two- to threefold more amylase than cells with the amyR1 plasmid, pAMY10. Deletion of DNA 5' to the alpha-amylase promoter, including deletion of the A + T-rich inverted repeat found in amyR1 and amyR2, had no effect on expression or transcription of alpha-amylase. Deletion of DNA 3' to the amyR1 promoter did not impair temporal activation of chloramphenicol acetyltransferase in amyR1-cat-86 transcriptional fusions, but catabolite repression was abolished. When an 8-base-pair linker was inserted in pAMY10 at the same site from which the 3' deletion was made, amylase expression doubled and was repressed less by glucose. Both the deletion and the insertion disrupted four bases at the 3' end of the putative amylase operator region. Site-directed mutagenesis was used to change bases in the promoter-operator region of amyR1 to their amyR2 counterparts. Either change alone increased amylase production twofold, but only the change at +7, next to the linker insertion of 3' deletion site, yielded the increased amylase activity in the presence of glucose that is characteristic of the amyR2 strain. The double mutant behaved most like strains carrying the amyR2 allele.

Cloning of the flagellin gene from Bacillus subtilis and complementation studies of an in vitro-derived deletion mutation

The flagellin promoter and structural gene from Bacillus subtilis I168 was cloned and sequenced. The amino-terminal protein sequence deduced from the coding sequence of the cloned gene was identical to that of the amino terminus of purified flagellin, indicating that the export of this protein is not directed by a posttranslationally processed N-terminal signal peptide. A sequence that was homologous to that of a consensus sigma 28 RNA polymerase recognition site lay upstream of the proposed translational start site. Amplification of this promoter region on a multicopy plasmid resulted in the formation of long, filamentous cells that accumulated flagellin intracellularly. The chromosomal locus containing the wild-type flagellin allele was replaced with a defective allele of the gene (delta hag-633) that contained a 633-base-pair deletion. Transport analysis of various flagellin gene mutations expressed in the hag deletion strain suggest that the extreme C-terminal portion of flagellin is functionally involved in export of the protein.

Bacillus licheniformis alpha-amylase gene, amyL, is subject to promoter-independent catabolite repression in Bacillus subtilis

Expression of the Bacillus licheniformis alpha-amylase gene, amyL, was temporally activated and subject to catabolite repression both in its natural host and when cloned on a 3.55-kilobase fragment in Bacillus subtilis. A subclone from which the promoter region of amyL and sequences upstream from the promoter were deleted had a low level of amylase activity. Expression of the promoterless gene was still subject to repression by glucose when the gene was present either on a multicopy plasmid or integrated into the B. subtilis chromosome. Catabolite repression occurred independently of the amylase promoter and irrespective of the distance of the promoterless amyL gene from the promoter which transcribed it. The transcriptional start sites of amyL activated by its own promoter and by a vector sequence promoter were determined by S1 mapping. alpha-Amylase-specific mRNA levels were measured in repressing and nonrepressing media, and catabolite repression was found to act at the level of transcription.

Microbial amylolytic enzymes

Starch-degrading, amylolytic enzymes are widely distributed among microbes. Several activities are required to hydrolyze starch to its glucose units. These enzymes include alpha-amylase, beta-amylase, glucoamylase, alpha-glucosidase, pullulan-degrading enzymes, exoacting enzymes yielding alpha-type endproducts, and cyclodextrin glycosyltransferase. Properties of these enzymes vary and are somewhat linked to the environmental circumstances of the producing organisms. Features of the enzymes, their action patterns, physicochemical properties, occurrence, genetics, and results obtained from cloning of the genes are described. Among all the amylolytic enzymes, the genetics of alpha-amylase in Bacillus subtilis are best known. Alpha-Amylase production in B. subtilis is regulated by several genetic elements, many of which have synergistic effects. Genes encoding enzymes from all the amylolytic enzyme groups dealt with here have been cloned, and the sequences have been found to contain some highly conserved regions thought to be essential for their action and/or structure. Glucoamylase appears usually in several forms, which seem to be the results of a variety of mechanisms, including heterogeneous glycosylation, limited proteolysis, multiple modes of mRNA splicing, and the presence of several structural genes.

A single gene directs synthesis of a precursor protein with beta- and alpha-amylase activities in Bacillus polymyxa

The Bacillus polymyxa amylase gene comprises 3,588 nucleotides. The mature amylase comprises 1,161 amino acids with a molecular weight of 127,314. The gene appeared to be divided into two portions by the direct-repeat sequence located at almost the middle of the gene. The 5' region upstream of the direct-repeat sequence was shown to be responsible for the synthesis of beta-amylase. The 3' region downstream of the direct-repeat sequence contained four sequences homologous with those in other alpha-amylases, such as Taka-amylase A. The 48-kilodalton (kDa) amylase isolated from B. polymyxa was proven to have alpha-amylase activity. The amino acid sequences of the peptides generated from the 48-kDa amylase showed complete agreement with the predicted amino acid sequence of the C-terminal portion. The B. polymyxa amylase gene was therefore concluded to contain in-phase beta- and alpha-amylase-coding sequences in the 5' and 3' regions, respectively. A precursor protein, a 130-kDa amylase, directed by a plasmid, pYN520, carrying the entire amylase gene, had both beta- and alpha-amylase activities. This represents the first report of a single protein precursor in procaryotes that gives rise to two enzymes.

Sequence and analysis of the DNA encoding protective antigen of Bacillus anthracis

The nucleotide sequence of the protective antigen (PA) gene from Bacillus anthracis and the 5' and 3' flanking sequences were determined. PA is one of three proteins comprising anthrax toxin; and its nucleotide sequence is the first to be reported from B. anthracis. The open reading frame (ORF) is 2319 bp long, of which 2205 bp encode the 735 amino acids of the secreted protein. This region is preceded by 29 codons, which appear to encode a signal peptide having characteristics in common with those of other secreted proteins. A consensus TATAAT sequence was located at the putative -10 promoter site. A Shine-Dalgarno site similar to that found in genes of other Bacillus sp. was located 7 bp upstream from the ATG start codon. The codon usage for the PA gene reflected its high A + T (69%) base composition and differed from those of genes for bacterial proteins from most other sequences examined. The TAA translation stop codon was followed by an inverted repeat forming a potential termination signal. In addition, a 192-codon ORF of unknown significance, theoretically encoding a 21.6-kDa protein, preceded the 5' end of the PA gene.

Cloning and expression in Escherichia coli of two additional amylase genes of a strictly anaerobic thermophile, Dictyoglomus thermophilum, and their nucleotide sequences with extremely low guanine-plus-cytosine contents

An obligately anaerobic and extremely thermophilic bacterium, Dictyoglomus thermophilum, produces multiple extracellular amylases. In addition to one of the amylase genes, amyA, which we previously cloned and characterized, we have cloned two additional genes, amyB and amyC, coding for amylases of this thermophile, into Escherichia coli and determined their nucleotide sequences. The two amylase genes were expressed under the control of E. coli promoters. Almost all activity was detected in the intracellular fraction in the E. coli cells. The molecular mass and NH2-terminal amino acid sequence of the AmyB enzyme, which was purified from an E. coli transformant containing the amyB gene, confirmed that the reading frame of amyB consisted of 562 amino acids (Mr 67,000). The molecular mass of the AmyC enzyme, estimated by activity staining of a crude extract of E. coli containing amyC, confirmed that AmyC consisted of 498 amino acids (Mr 59,000). The optimal temperatures for AmyB and AmyC activities on soluble starch were 80 degrees C and 70 degrees C, respectively. Both AmyB and AmyC showed a pH optimum of 5.5. AmyB and AmyC showed a different pattern of starch hydrolysis when examined by thin-layer chromatography. Some homology in the amino acid sequences with the functional regions of Taka-amylase A was found in both AmyB and AmyC. The codon usage in the amyA, amyB and amyC genes was highly biased, which reflects the fact that the guanine-plus-cytosine (G + C) content of DNA of D. thermophilum is 29 mol%. The distribution of G and C at each position of the codons was non-random; the G + C content of the first position of codons is significantly high, whereas that of the third position is somewhat low. In addition, codons consisting only of A and T were preferentially used in this thermophile.

Molecular cloning of the barley seed protein CMd: a variant member of the alpha-amylase/trypsin inhibitor family of cereals

The nucleotide and deduced amino-acid sequences of a cDNA clone encoding the barley seed protein CMd are described. The sequence is homologous with those of a family of inhibitors of alpha-amylase and trypsin, except for two short insertions. The longest of these (14 residues) is at the junction between the three proposed ancestral regions that comprise this family of proteins, and has limited identity with alpha-amylases of bacterial origin.

Alpha-amylase structure and activity

Two computerized methods of predicting protein secondary structure from amino acid sequences are evaluated by using them on the alpha-amylase of Aspergillus oryzae, for which the three-dimensional structure has been determined. The methods are then used, with amino acid alignments, to predict the structures of other alpha-amylases. It is found that all alpha-amylases of known amino acid sequence have the same basic structure, a barrel of eight parallel stretches of extended chain surrounded by eight helices. Strong similarities are found in those areas of the proteins believed to bind an essential calcium ion and at that part of the active site that catalyzes bond hydrolysis in the substrates. The active site, as a whole, is formed mainly of amino acids situated on loops joining extended chain to the adjacent helix. Variations in the length and amino acid sequence of these loops, from one alpha-amylase to another, provide the differences in binding the substrates believed to account for the known variations in action pattern of alpha-amylases of different biological origins.

Detection of protein similarities using nucleotide sequence databases

A simple procedure is described for finding similarities between proteins using nucleotide sequence databases. The approach is illustrated by several examples of previously unknown correspondences with important biological implications: Drosophila elongation factor Tu is shown to be encoded by two genes that are differently expressed during development; a cluster of three Drosophila genes likely encode maltases; a flesh-fly fat body protein resembles the hypothesized Drosophila alcohol dehydrogenase ancestral protein; an unknown protein encoded at the multifunctional E. coli hisT locus resembles aspartate beta-semialdehyde dehydrogenase; and the E. coli tyrR protein is related to nitrogen regulatory proteins. These and other matches were discovered using a personal computer of the type available in most laboratories collecting DNA sequence data. As relatively few sequences were sampled to find these matches, it is likely that much of the existing data has not been adequately examined.

cis-acting sites in the transcript of the Bacillus subtilis trp operon regulate expression of the operon

Transcription of the trp operon of Bacillus subtilis is regulated by attenuation. A trpE'-'lacZ gene fusion preceded by the wild-type trp promoter-leader region was used to analyze regulation. Overproduction of the trp leader transcript in trans from a multicopy plasmid caused constitutive expression of the chromosomal trpE'-'lacZ fusion, presumably by titrating a negative regulatory factor encoded by the mtr locus. Subsegments of the trp leader region cloned onto the multicopy plasmid were examined for their abilities to elevate beta-galactosidase activity. An RNA segment spanning the portion of the leader transcript that forms the promoter-proximal strand of the proposed antiterminator structure was most active in this trans test. The data suggest that the mtr gene product, when activated by tryptophan, binds to this RNA segment and prevents formation of the antiterminator. In this manner, the trans-acting factor promotes formation of the RNA structure that causes transcription termination. Secondary-structure predictions for the leader segment of the trp operon transcript suggest that if the mtr factor bound this RNA segment in a nonterminated transcript, the ribosome-binding site for the first structural gene, trpE, could be sequestered in a stable RNA structure. We tested this possibility by comparing transcriptional and translational fusions containing the initial segments of the trp operon. Our findings suggest that the mtr product causes both transcription attenuation and inhibition of translation of trpE mRNA. Inhibition of translation initiation would reduce ribosome density on trpE mRNA, perhaps making it more labile. Consistent with this interpretation, the addition of tryptophan to mtr+ cultures increased the rate of trpE'-'lacZ mRNA decay.

Evidence for movement of the alpha-amylase gene into two phylogenetically distant Bacillus stearothermophilus strains

The gene for an alpha-amylase cloned from strain DY-5 of Bacillus stearothermophilus was used to examine to what extent the corresponding genes are structurally similar in other B. stearothermophilus strains. The structure of the gene itself was almost identical in DY-5 and a group of strains represented by strain 799. The gene was not detected at all in strain DSM2334, which was phenotypically amylase deficient. Comparison of the structure of 5S rRNA and electrophoretic pattern of the ribosomal proteins indicates that strains DY-5 and DSM2334 are closely related to each other, whereas strain 799 is phylogenetically very distant from the two. We estimate that strain 799 separated from DY-5 and DSM2334 some 420 million years ago. Nucleotide sequencing of the region containing the amylase gene from strains DY-5 and 799 revealed the presence of a 3.4-kilobase stretch that was highly similar in the two strains. Furthermore, comparison of the restriction map surrounding the amylase gene of DY-5 with that of a corresponding region in DSM2334 indicated that the former strain contained an extra segment 5.5 kilobases in length, which included the 3.4-kilobase stretch mentioned above. This segment was missing in DSM2334. It thus appears that the alpha-amylase gene was brought into strains DY-5 and 799 from outside despite a large phylogenetic distance.

Catabolite repression-resistant mutations of the Bacillus subtilis alpha-amylase promoter affect transcription levels and are in an operator-like sequence

The amyR1 locus controls the regulated transcription of amyE, the structural gene encoding alpha-amylase in Bacillus subtilis. Transcription of amyE is activated in early stationary phase cells, and can be repressed by rapidly metabolized carbon sources such as glucose. Transcription of amyE initiates in vitro from a promoter recognized by the major vegetative form of RNA polymerase, E sigma 43. S1 nuclease mapping of in-vivo amylase transcripts suggests that this promoter is also used in vivo. Two independently isolated cis-acting mutations, gra-5 and gra-10, which abolish glucose-mediated repression of amylase synthesis without altering temporal activation, were determined by DNA sequencing to result from a G.C to A.T transition at a position located five base-pairs downstream from the start site of transcription. While this is the first example of a site involved in catabolite repression of gene expression in a Gram-positive micro-organism, the region surrounding the gra mutations shows considerable homology to certain cis-acting regulatory loci in Escherichia coli, suggesting that such sequences have been evolutionarily conserved.

alpha-Amylase gene of Streptomyces limosus: nucleotide sequence, expression motifs, and amino acid sequence homology to mammalian and invertebrate alpha-amylases

The nucleotide sequence of the coding and regulatory regions of the alpha-amylase gene (aml) of Streptomyces limosus was determined. High-resolution S1 mapping was used to locate the 5' end of the transcript and demonstrated that the gene is transcribed from a unique promoter. The predicted amino acid sequence has considerable identity to mammalian and invertebrate alpha-amylases, but not to those of plant, fungal, or eubacterial origin. Consistent with this is the susceptibility of the enzyme to an inhibitor of mammalian alpha-amylases. The amino-terminal sequence of the extracellular enzyme was determined, revealing the presence of a typical signal peptide preceding the mature form of the alpha-amylase.

Nucleotide sequence of the beta-cyclodextrin glucanotransferase gene of alkalophilic Bacillus sp. strain 1011 and similarity of its amino acid sequence to those of alpha-amylases

The nucleotide sequence of the gene for cyclodextrin glucanotransferase of alkalophilic Bacillus sp. strain 1011 was determined. The deduced amino acid sequence at the NH2-terminal side of the enzyme showed a high homology with the sequences of alpha-amylase in the three regions which constitutes the active centers of alpha-amylases.

Modulation of Bacillus subtilis alpha-amylase promoter activity by the presence of a palindromic sequence in front of the gene

Upstream of the promoter of the Bacillus subtilis alpha-amylase gene (amyE) derived from an alpha-amylase hyper-producing strain, there is an inverted repeat sequence (palindromic sequence), which has a free energy of 21.2 kcal/mol due to the formation of stable stem-loop structure. The role of the palindromic sequence for the expression of amyE was studied using a plasmid encoding the amyE'-'bla (E. coli beta-lactamase) fused gene in an alpha-amylase-deficient B. subtilis mutant as the host. By the presence of the palindromic sequence, the transcription activity of the amyE promoter was enhanced approximately 6 fold by starch (3%) in the medium and was less repressed by glucose.

Molecular cloning of an amylase gene of Bacillus circulans

An amylase gene of Bacillus circulans was cloned in B. subtilis and its nucleotide sequence was determined. The putative proamylase consists of 528 amino acids, which correspond to a molecular weight of 58,776. Homologous regions with other amylases of Bacillus species were found. A sigma 55-type promoter is located at about 250 bp upstream from the starting codon. This promoter was also functional in Escherichia coli, and able to express beta-galactosidase activity.

Endo-beta-1,4-glucanase gene of Bacillus subtilis DLG

The DNA sequence of the Bacillus subtilis DLG endo-beta-1,4-glucanase gene was determined, and the in vivo site of transcription initiation was located. Immediately upstream from the transcription start site were sequences closely resembling those recognized by B. subtilis sigma 43-RNA polymerase. Two possible ribosome-binding sites were observed downstream from the transcription start site. These were followed by a long open reading frame capable of encoding a protein of ca. 55,000 daltons. A signal sequence, typical of those present in gram-positive organisms, was observed at the amino terminus of the open reading frame. Purification of the mature exocellular beta-1,4-glucanase and subsequent amino-terminal protein sequencing defined the site of signal sequence processing to be between two alanine residues following the hydrophobic portion of the signal sequence. The probability of additional carboxy-terminal processing of the beta-1,4-glucanase precursor is discussed. S1 nuclease protection studies showed that the amount of beta-1,4-glucanase mRNA in cells increased significantly as the culture entered the stationary phase. In addition, glucose was found to dramatically stimulate the amount of beta-1,4-glucanase mRNA in vivo. Finally, the specific activities of purified B. subtilis DLG endo-beta-1,4-glucanase and Trichoderma reesei QM9414 endo-beta-1,4-glucanase (EC 3.2.1.4) were compared by using the noncrystalline cellulosic substrate trinitrophenyl-carboxymethyl cellulose.

Characterization of the sacQ genes from Bacillus licheniformis and Bacillus subtilis

The sacQ gene from Bacillus licheniformis was cloned and expressed in Bacillus subtilis. Deletion analysis shows that it encodes a 46-amino-acid polypeptide homologous to the B. subtilis sacQ gene product. The polypeptide, when it is overexpressed, activates the expression of a number of target genes in B. subtilis, all encoding secreted enzymes: alkaline protease, levansucrase, beta-glucanase(s), xylanase, and alpha-amylase. The maximum stimulations measured for alkaline protease and levansucrase were by a factor of 70 and 50, respectively, when the sacQ gene from B. licheniformis was present on a multicopy plasmid in B. subtilis. The sacQ genes from B. subtilis and B. licheniformis, cloned in the same multicopy plasmid, were compared under the same conditions. The sacQ gene from B. licheniformis was more efficient than the sacQ gene from B. subtilis in producing the hypersecretion phenotype. The sacQ structural genes from B. subtilis and B. licheniformis were placed under the control of the same inducible promoter. Hypersecretion was specifically obtained under conditions of full induction of the promoter. The target site of levansucrase regulation by sacQ was identified as a 440-base-pair fragment located in the 5' noncoding region of sacB, suggesting transcriptional control.

Sequence conservation and region shuffling in an endoglucanase and an exoglucanase from Cellulomonas fimi

Cellulomonas fimi produces an endoglucanase and an exoglucanase which bind strongly to cellulose. Each enzyme contains three distinct regions: a short sequence of about 20 amino acids containing only proline and threonine (the Pro-Thr box); an irregular region, rich in hydroxyamino acids, of low charge density, and which is predicted to have little secondary structure; and an ordered region of higher charge density which contains a potential active site, and which is predicted to have secondary structure. The Pro-Thr box is conserved almost perfectly in the two enzymes. The irregular regions are 50% conserved, and the conserved sequences include four Asn-Xaa-Ser/Thr sites. The ordered regions appear not to be conserved, but the potential active sites both have the sequence Glu-Xaa7-Asn-Xaa6-Thr; they occur at widely separated sites in the two regions. The order of the regions is reversed in the two enzymes: irregular-Pro-Thr box-ordered in the endoglucanase; ordered-Pro-Thr box-irregular in the exoglucanase. The genes for the two enzymes appear to have arisen by shuffling of two conserved sequences and either one or two other sequences.

The alpha-amylase gene in Drosophila melanogaster: nucleotide sequence, gene structure and expression motifs

We present the complete nucleotide sequence of a Drosophila alpha-amylase gene and its flanking regions, as determined by cDNA and genomic sequence analysis. This gene, unlike its mammalian counterparts, contains no introns. Nevertheless the insect and mammalian genes share extensive nucleotide similarity and the insect protein contains the four amino acid sequence blocks common to all alpha-amylases. In Drosophila melanogaster, there are two closely-linked copies of the alpha-amylase gene and they are divergently transcribed. In the 5'-regions of the two gene-copies we find high sequence divergence, yet the typical eukaryotic gene expression motifs have been maintained. The 5'-terminus of the alpha-amylase mRNA, as determined by primer extension analysis, maps to a characteristic Drosophila sequence motif. Additional conserved elements upstream of both genes may also be involved in amylase gene expression which is known to be under complex controls that include glucose repression.

Use of the Bacillus subtilis subtilisin signal peptide for efficient secretion of TEM beta-lactamase during growth

We report the development of an efficient Bacillus subtilis secretory system, with the secreted product stably maintained in the medium for 100 h. The system is based on characterization of the subtilisin signal peptidase cleavage site and promoters, catabolite repression of sporulation, presence of a vegetative secreting mechanism, and availability of a protease-deficient strain.

Nucleotide sequences of two cellulase genes from alkalophilic Bacillus sp. strain N-4 and their strong homology

Two genes for cellulases of alkalophilic Bacillus sp. strain N-4 (ATCC 21833) have been sequenced. From the DNA sequences the cellulases encoded in the plasmids pNK1 and pNK2 consist of 488 and 409 amino acids, respectively. The DNA and protein sequences of the pNK1-encoded cellulase are related to those of the pNK2-encoded cellulase. The pNK2-encoded cellulase lacks the direct repeat sequence of a stretch of 60 amino acids near the C-terminal end of the pNK1-encoded cellulase. The duplication of the cellulase genes and the formation of the direct repeat in the pNK1-encoded cellulase occurred at almost the same time.

Cloning in Escherichia coli of a Bacillus subtilis arginine repressor gene through its ability to confer structural stability on a fragment carrying genes of arginine biosynthesis

The structural stability of a previously isolated recombinant plasmid pUL720 was examined. pUL720 contains an insert in pBR322 of 23.8 kbp comprising 4 EcoR1 fragments of sizes 12 kbp and 6 kbp, both of which are homologous to the B. subtilis genome, and 5 kbp and 0.8 kbp (of unknown origin). The 12 kbp fragment, which encodes the arginine biosynthesis genes argA-F-cpa, cannot be cloned in isolation in a high copy vector in E. coli but can be inserted into a low copy vector pGV1106 to generate pUL800. Deletion analysis of pUL720 indicated that the 5 kbp and 0.8 kbp fragments were not necessary to maintain plasmid stability. The 6 kbp fragment, when cloned into the EcoR1 site in pACYC184 to generate pUL2030, permitted the cloning in trans in pBR322 of the 12 kbp fragment or subclones containing the instability region. The minimum inhibitory concentration of kanamycin determined in the B. subtilis argC-neo transcriptional fusion pUL730 and expression of the argF gene product, ornithine carbamoyltransferase (OCTase), in pUL800 were reduced by approximately 3 and 2 fold respectively under conditions of arginine excess and in the presence of pUL2030. B. subtilis partial diploids were constructed by transforming parental and arginine hydroxamate resistant (Ahr) mutants with pUL2100, a plasmid generated by inserting the 6 kbp fragment into the integration vector pJH101. The 6 kbp fragment complemented and restored parental type levels of OCTase in ahrC mutants.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of Bacillus subtilis levansucrase gene expression by sucrose and regulation of the steady-state mRNA level by sacU and sacQ genes

In Bacillus subtilis, the extracellular enzyme levansurcrase is synthesized in the presence of sucrose. A termination structure between the transcription start site and the structural gene was the apparent site for regulation by sucrose of transcription into the structural gene. Sequence analysis of the sacB leader region from two strains constitutive for levansucrase synthesis showed a single base change in the stem of this termination structure. This single base change also led to the constitutive synthesis of a sacB'-'lacZ fusion, whereas the wild-type sacB'-'lacZ fusion was induced by the addition of sucrose. S1 nuclease mapping of sacB transcripts with probes labeled either within the termination structure or 3' to the termination structure showed that sucrose did not increase the number of transcripts extending into the termination structure; however, sucrose did increase the number of transcripts extending past the termination structure. Two pleiotropic mutations which affect the expression of levansucrase, sacQ36 hyperproducing [sacQ36(Hy)] and sacU32(Hy), were separately introduced into the strain carrying the sacB'-'lacZ fusion. These mutations each increased the expression levels of the sacB'-'lacZ fusion. S1 mapping showed increased levels of transcript initiating at the sacB promoter in strains with the sacQ36(Hy) and sacU32(Hy) mutations. This increased transcription appeared to be independent of the sucrose-regulated transcription termination, suggesting the existence of at least two different mechanisms for the regulation of sacB expression.

Isolation and characterization of a 2.2-kb operon preceding the alpha-amylase gene of Bacillus amyloliquefaciens

A DNA region of 2.8 X 10(3) base pairs (2.8 kb) upstream of the Bacillus amyloliquefaciens alpha-amylase gene has been isolated. This DNA gave rise to a 2.2-kb transcript. The 3' end of the transcript was mapped with S1 nuclease and shown to terminate 49 base pairs upstream of the -35 region of the alpha-amylase promoter. In B. subtilis minicells this 2.2-kb transcript coded for three different polypeptides, thus indicating a polycistronic operon-type structure. The location and the order of the polypeptides were established using DNA deletions. The joining of the 2.2-kb operon to the downstream alpha-amylase gene in the plasmid pUB110 did not have any significant effect on the level of expression of the alpha-amylase.

The effect of the inverted repeat structure on the production of the cloned Bacillus amyloliquefaciens alpha-amylase

An inverted repeat structure from Bacillus natto preceding the Bacillus subtilis alpha-amylase gene has been suggested to be responsible for the enhancement of alpha-amylase production [Yamazaki et al. (1983) J. Bacteriol. 156, 327-337]. A similar inverted repeat region has also been found upstream from the Bacillus amyloliquefaciens alpha-amylase gene and shown to function as a transcription termination signal of an upstream operon of 2.2 X 10(3) bases (2.2 kb) (Kallio et al., following paper in this journal). The removal of this DNA region reduced the level of alpha-amylase production by 70% and led to concomitant formation of a readthrough transcript arising from the promoter of the 2.2-kb operon. To test whether the readthrough transcript affected the alpha-amylase production, the promoter of the 2.2-kb operon was removed from plasmid constructions carrying either intact or deleted inverted repeat sequences. When cultures carrying the above plasmids were assayed for alpha-amylase activity, both constructions produced equal amounts of alpha-amylase. Thus, the inverted repeat structure preceding the alpha-amylase promoter does not, as such, enhance the alpha-amylase production. Instead, its presence prevents the inhibition of alpha-amylase expression caused by the readthrough transcripts from the upstream promoter.

Amplification of the amyE-tmrB region on the chromosome in tunicamycin-resistant cells of Bacillus subtilis

In a class of tunicamycin-resistant mutants (tmrA7) of Bacillus subtilis, the production of extracellular alpha-amylase is increased by about five fold. The tmrA7 characteristics (tunicamycin resistance and hyperproduction of extracellular alpha-amylase) can be transferred to recipient cells by transformation. In the transformants and the original tmrA7 mutant, typical amplification of the region from 4 kb upstream of the amyE gene to the tmrB gene on the chromosome was detected. The repeating unit, 16 kb in size, repeats tandemly about five and ten times in the mutant and transformants, respectively, and the alpha-amylase production is proportional to the copy number of the amyE gene. Simultaneous amplification of the tmrB gene, which is responsible for tunicamycin resistance in the multicopy state, and the alpha-amylase structural gene (amyE) seems to be the cause of the pleiotropy of the tmrA7 mutation.

5'-noncoding region sacR is the target of all identified regulation affecting the levansucrase gene in Bacillus subtilis

The regulation of the levansucrase gene sacB was studied in Bacillus subtilis strains. Fusions were constructed in which genes of cytoplasmic proteins such as lacZ were placed immediately downstream from sacR, the regulatory region located upstream from sacB. These fusions were introduced in mutants affected in sacB regulation. In all cases the marker gene was affected in the same way as sacB by the genetic context. This result is of particular interest for the sacU pleiotropic mutations, which affect sacB expression and other cellular functions such as the synthesis of several exocellular enzymes. We also showed that strains harboring sacU+ or sacU-hyperproducing alleles contained different amounts of sacB mRNA, which was proportional to their levansucrase secretion. We concluded that the sacU gene does not affect sacB expression at the level of secretion but acts on a target within sacR. We discuss the possibility that sacU acts on a part of sacR, a homologous copy of which was found upstream from the gene of another sacU-dependent secreted enzyme of B. subtilis, beta-glucanase.

Novel form of transcription attenuation regulates expression the Bacillus subtilis tryptophan operon

Transcription of the trp operon of Bacillus subtilis is regulated in response to the availability of tryptophan. The first structural gene of the operon is preceded by a 204-base-pair transcribed leader region that contains a segment with the features of a procaryotic termination site. Transcription of the leader region was analyzed in vivo and in vitro to determine whether this putative termination site was used to regulate operon expression. When RNA was isolated from wild-type cells grown in the presence of excess tryptophan, transcripts of the operon ended at the putative termination site. In contrast, RNA isolated from cells grown in the absence of tryptophan or from a mutant strain which is constitutive for trp operon expression contained trp transcripts that extended beyond the termination site into the structural genes. To assess termination quantitatively in vivo, a trpE-lacZ fusion was constructed in which the trp promoter and leader region controls hybrid beta-galactosidase formation. The effects on hybrid beta-galactosidase levels of point mutations and deletions introduced into this leader region were determined. The results obtained establish that transcription of the trp operon structural genes is regulated in the leader region. This regulation appears to be mediated by the formation of alternative secondary structures of the leader transcript. In vitro transcription studies with wild-type and mutant templates provided additional evidence that the identified alternative RNA secondary structures regulate transcription termination. We hypothesize that binding of a tryptophan-activated regulatory protein to a specific segment of the nascent leader transcript prevents formation of one of the alternative secondary structures, thereby directing RNA polymerase to terminate transcription.