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J Biomed Biotechnol. 2010; 2010: 980567.
Published online 2010 September 21. doi:  10.1155/2010/980567
PMCID: PMC2947863

Constitutive High Level Expression of an Endoxylanase Gene from the Newly Isolated Bacillus subtilis AQ1 in Escherichia coli


A xylanolytic bacterium was isolated from the sediment of an aquarium. Based on the 16S rDNA sequence as well as morphological and biochemical properties the isolate was identified and denoted as Bacillus subtilis (B. subtilis) AQ1 strain. An endoxylanase-encoding gene along with its indigenous promoter was PCR amplified and after cloning expressed in E. coli. In E. coli the recombinant enzyme was found in the extracellular, in the cytoplasmic, and in the periplasmic fraction. The specific activity of the extracellular AQ1 recombinant endoxylanase after 24-hour fermentation was very high, namely, 2173.6 ± 51.4 and 2745.3 ± 11 U/mg in LB and LB-xylan medium, respectively. This activity was clearly exceeding that of the native B. subtilis AQ1 endoxylanase and that of 95% homologous recombinant one from B. subtilis DB104. The result shows that the original AQ1 endoxylanase promoter and the signal peptide gave a very high constitutive extracellular expression in E. coli and hence made the production in E. coli feasible.

1. Introduction

1,4-β-Endoxylanase (EC catalyzes the cleavage of the xylan backbone at the 1–4 carbon linkages to produce xylose and xylooligosaccharides. Xylanases have numerous biotechnological applications, both alone and in combination with other enzymes. Second only to cellulose, xylan is one of the most abundant polymers in the world. Along with other xylanolytic enzymes, endoxylanase works synergistically to convert the polymer finally into useful products such as art paper [1], xylose, low-calorie sweetener (xylitol), or bioethanol [2]. Furthermore, xylanases have the potential to reduce the use of environmentally harmful chemicals in the pulp and paper industry and are considered as potential biocatalysts in deinking processes for recycled paper [3]. Additionally, xylooligosaccharides as products of xylan degradation can be used as ingredients in functional food and pharmaceutical products [4].

Xylanases from a panoply of different microorganisms have been described [2, 5], and based on sequence similarities, the enzymes are classified into two glycosyl hydrolases families, that is, family 10 and family 11 [6]. Enzymes belonging to the former family routinely display high molecular masses (more than 40 kDa) whereas those belonging to family 11 have molecular masses of approximately 20 kDa or even below. Family 10 xylanases usually have also detectable cellulolytic activities in addition to their xylanolytic activities whereas members of family 11 do not exhibit such activity [7].

Xylanolitic bacteria from Indonesian habitats have been isolated by our laboratory. Cloning and expression of an endoxylanase gene from a local Bacillus licheniformis into E. coli using an E. coli plasmid promoter have previously been conducted [8]. In this paper, we describe the cloning and efficient expression of a family 11 xylanase gene (xyn11) governed by its own promoter. The gene originates from a B.subtilis xylanolytic strain that was newly isolated and identified. Endoxylanase production of the isolate was compared to recombinant one expressed in E. coli and to the homolog of recombinant endoxylanase coming from B. subtilis strain DB104.

2. Materials and Methods

2.1. Biochemical Characterization and Carbohydrate Metabolic Profile

The bacterium was isolated as a xylanase producer strain from the sediment of a small aquarium in Serpong/Indonesia. A single colony with a clearing zone on xylan-supplemented LB agar plate was picked and designated as AQ1. Standard microbiological techniques were applied to determine morphological characteristics such as colony and cell shape, Gram and spore staining. Biochemically, isolate AQ1 was checked for catalase activity, urease reaction, nitrate reduction, starch hydrolysis, indole hydrolysis, and gas formation. Carbohydrate source utilization experiments were carried out applying the API 50 CHB system (bioMérieux, Nürtingen, Germany) and analyzed with the APILAB PLUS 3.3.3 software.

2.2. Bacterial Strains, Plasmids, and Media

Chromosomal DNA from isolate AQ1 was extracted as previously described in [8] and served as the basis for PCR amplification of the AQ1 endoxylanase, and 16S rRNA gene. Plasmid maintenance and expression were done in E. coli DH5α (genotypes: FendA1 hsdR17 (rkmk+), supE44 thi1 recA1 gyrA (Nalr), relA1D (lacZYAargF), U169 (Ø80lacZDM15)). The plasmid used for cloning and expression was pGEM-T easy (Promega, USA). 1.5% (w/v) agar Luria-Bertani (LB) plate media containing 100 μg/mL (w/v) ampicillin, 50 μg/mL (w/v) 5-bromo-4-chloro-3-indolyl-β-Dgalactopyranoside (X-gal), and 1 mM isopropyl-β-thiogalactopyranoside (IPTG) were used for selection of E. coli harbouring recombinant plasmids. DNA cloning, PCR, and plasmid preparation followed standard protocols as in the work of Sambrook and Russel 2001 [10]. LB agar medium containing ampicillin (50 μg/mL) and 0.7% (w/v) oat spelt xylan was used for monitoring xylanase expression.

2.3. 16S Ribosomal RNA Gene Amplification

Amplification by PCR with universal primers 16S-27f (5′-GAGTTTGATCCTGGCTCAG-3′) and 16S-1525r (5′-AGAAAGGAGGTGATCCAGCC-3′) for bacterial 16 rRNA gene was conducted using Taq DNA polymerase (NEB, Hitchin, United Kingdom) under the following conditions After initial 5-minute hot start incubation at 94°C, the mixture was introduced to 30 cycles, each cycle including 1 min at 94°C, 35 s at 50°C, and 2 min at 72°C, then 5 min at 72°C for elongation using a thermal cycler (Eppendorf, Germany). The amplified 16S rRNA gene was then purified using High Pure PCR Clean Up Kit (Roche, Germany). The sequencing was performed by ABI 3100 DNA Sequencer. The primers used for sequencing were as follows: 16S-27f, 16S-343r (5′-CTGCTGCCTCCCGTA-3′), 16S-357f (5′-TACGGGAGGCAGCAG-3′), 16S-519r (5′-G(T/A)ATTACCGCGGC(T/G)GCTG-3′), 16S-536f (5′-CAGC(C/A)GCCGCGGTAAT(T/A)C-5′), 16S-803f (ATTAGATACCTGGTAG-3′), 16S-907r (5′-CCGTCAATTCATTTAGTTT-3′), 16S-114f (5′-GCAACGAGCGCAACCC-3′), 16S-1385r (5′-CGGTGTGT(A/G)CAAGGCCC-3′), and 16S-1525r (5′-AGAAAGGAGGTGATCCAGCC-3′). The DNA sequences were analyzed using Clone Manager Software (Sci-Ed Software, North Carolina, USA).

2.4. Xylanase Gene Amplification, Cloning, and Sequencing

The primers for the amplification of xylanase gene (xyn) and its promoter were designed based on the B. subtilis strain 168 genome sequence ( (5′-GGGGTACCTAGCGTTATTATACTGAAGGGGACGATC-3′) served as a forward primer and (5′-GAAGATCTTTACCACACACTGTTACGTTAGAACTTCC-3′) as the reverse primer with the underlined nucleotides showing the restriction enzyme site of underlined ones being KpnI and BglII, respectively. PCR amplification with Taq polymerase using the above primers and the extracted chromosomal DNA of isolate AQ1 as the template was carried out under the following conditions: initial 94°C for 3 min for hot start, then 30 cycles of 94°C 45 s, 52°C 1 min, and 72°C 2 min for each cycle. The PCR product with the predicted size then was extracted and purified from the agarose gel with the Gel extraction Kit (Gene Aid, Taipei County, Taiwan), and after ligating it into the TA cloning vector pGEM T-easy the recombinant plasmid was transformed into E.coli DH5 α. The confirmed recombinant pGEM T-easy plasmid was cut by EcoRI and the xyn gene was removed. The remained vector then religated and transformed into E. coli DH5 α, and this clone was used as a negative control. The xyn gene from B. subtilis DB104, that is, a derivative of B. subtilis strain 168 ( was also cloned and expressed in the exactly same procedure. For comparison, the AQ1 endoxylanase gene lacking its indigenous promoter was also cloned into pGEM T-easy with the forward primer being 5′-AATGCGGCCGCAATGTTTAAGTTTAAAAAGAATTTCT-3′ and the reverse primer 5′-GCTCTAGATTACCACACCACTGTTACGTTAGAACTT-3′ then transformed into E. coli DH5 α. The recombinant E. coli containing this recombinant plasmid was used for xylanase activity assay in the absence of native putative promoter in the gene. Then from this plasmid the ORF was removed and subcloned behind the T7 promoter in the pBAD/IIIg vector in E.coli Top 10 as previously described between sites Not I and EcoR I [8]. That's done used for determining the molecular mass. For obtaining optimal expression of the gene, induction was done by adding arabinose (0%–0.2%) as suggested in the plasmid vector manual. Sequencing of endoxylanase gene was done using primers matching vector sequences. The DNA sequence was analyzed by performing BLAST searches (

2.5. Analysis for 16S rDNA and Endoxylanase Gene

The phylogenetic tree data were obtained by alignment of the different 16S rDNA sequences through the server database using the program CLUSTAL W version 1.8 [11] and Basic Local Alignment Search Tool (BLAST; National Center for Biotechnology Information ( with the standard parameters. The alignments were visually corrected when necessary by GeneDoc Software. Phylograms were obtained by the neighbor-joining method [11]. The following endoxylanase genes used in multiply alignment analyses were retrieved from GenBank: Bfirm: from Bacillus firmus (AAQ83579); Paenibac: from PaeniBacillus sp (DQ869568); Apunctata: from Aeromonas Punctata (D32065).

GenBank Accession Number; The sequences of the 16S rDNA and the endoxylanase gene from this strain AQ1 were then submitted to Genbank.

2.6. Molecular Mass Determinations and Electrophoresis Analysis

The apparent molecular mass of the recombinant endoxylanase was determined using Arabinose induction of AQ1 xylanase gene cloned in E.coli with inducible T7 promoter (vector pBAD/IIIg). The induction using different arabinose concentrations (0%–0.2%) was conducted based on the plasmid vector manufacturer's manual. The molecular mass was determined by 0.1% sodium dodecyl sulfate (SDS) and 10% polyacrylamide gel electrophoresis (PAGE). Standards employed were phosphorylase (97 kDa), albumin (66 kDa), ovalbumin (45 kDa), carbonic anhydrase (30 kDa), soybean trypsin inhibitor (20.1 kDa), and α-lactalbumin (14.4 kDa).

2.7. Enzyme Preparation from Wild Type Strain

Bacterial strains, B. subtilis strain AQ1 and strain DB104, were streaked on LB xylan-agar medium, and a single colony with clear zone was picked and inoculated in 5 mL of each different medium (including LB and LB xylan) and growth overnight (~12 hours until OD600 = ~0.9), and 0.625 mL of this inoculum was refreshed in a new medium 25 mL in 125 mL Erlenmeyer flasks at 150 rpm at 37°C for 24 hours (Kuehner Shaker, Switzerland). Subsequently the supernatant was used as sample for the enzyme assays.

2.8. Enzymes from Recombinant E. coli

E. coli DH5α expressing the recombinant xylanases was either cultivated as the same method as above mentioned in 25 mL LB or in LB containing oat spelt xylan at different concentrations: 0.1 and 1%, respectively. Media were supplemented with ampicillin (50 μg/mL) at 37°C and cultivated on a shaker (Kuehner Shaker, Switzerland) at 150 rpm for 16 or 24 hours. For confirmation E. coli DH5 α containing an empty circularized pGEM T-easy plasmid and E. coli DH5 α containing a recombinant pGEM T-easy containing only ORF of AQ1 xylanase, were cultivated and analyzed in the same way to confirm that the xylanase activity is due to the presence of AQ1 xyn with its original promoter in the recombinant plasmid pGEM-T easy.

Extracellular fractions were obtained from the supernatant by centrifugation. The cells were subjected to periplasmic fraction preparation which was obtained based on the method described by Huang et al. 2006 [12] by adding the same volume of chloroform to cells suspended in 6.25 mL of phosphate buffer then incubated at room temperature for 20 minutes. Then the sample was centrifuged and the aqueous phase containing periplasmic fraction was obtained and used for enzyme assay. The remaining cell pellets from the previous procedure were subjected to cytoplasmic fractions. The cytoplasmic fraction was obtained as follows. The precipitated cells were suspended in 6.25 mL of 20 mM phosphate buffer, pH 7, containing 1 mM mercaptoethanol, then disrupted by sonication (Heat systemXL Ultrasonicator, Japan) at the maximum frequency for 30 s on and 30 s off repeatedly for 5 times at 4°C, and then centrifuged and the supernatant was taken. This cytoplasmic fraction was then subjected to the enzyme assay. As a control for knowing the effect of heat from ultrasonication activity on the total activity, the same amount of culture was sonicated directly, then the supernatant containing all cellular fractions (cytoplasmic, periplasmic, and extracellular) was obtained after centrifugation. This was used as a sample for determining the total activity of all cellular fractions. For E. coli DH5 α containing a recombinant pGEM T-easy with DB104 xylanase gene, only the extracellular fraction was taken.

2.9. Assay of Enzyme Activities on Agar Plates

Each 1 μL of the same amount of cell number (OD600 = ~0.9) of culture of recombinant E. colis was spotted on LB agar medium containing xylan with ampicillin and incubated at 37°C overnight. Then the clearing zones around the colony were observed.

2.10. Effect of pH and Temperature on Enzyme Activity and Thermostability

The effect of the temperature on extracellular endoxylanase activity was measured in the temperature range of 35–80°C at pH 7 using 50 mM sodium phosphate buffer. The effect of the pH on the activity was measured at 55°C within pH range of 5–11 using 50 mM of the following buffers: citrate buffer (for pH 5, 6), sodium phosphate buffer (for pH 6–8), Tris–HCl buffer (for pH 8–10), and Glysin–NaOH buffer (pH 10-11). Thermostability of the enzyme was measured at 50°C using 50 mM sodium phosphate pH 7 after preincubating in 50, 55, and 60°C for 10, 20, and 30 min. The protein concentration was measured by means of the dye-binding assay method of Bradford and bovine serum albumin (BSA) as the standard protein [13].

2.11. Enzyme Assay

Xylanase activity was measured (each sample in triplicates) based on the Miller method using dinitrosalicylic acid to quantify reducing sugar, D-xylose was used as the standard [14, 15]. 50 μl crude extract at appropriate dilutions in phosphate buffer was mixed with 450 μl of 1% oat spelt xylan in 50 mM of buffer at indicated pH. The mixture was then incubated at the indicated temperature for 5 min; subsequently, 750 μl of DNS reagent (1% dinitrosalicylic acid, 0.2% phenol, 0.05% sodium sulfite, and 1% sodium hydroxide, 20% (w/v) potassium sodium tartrate) was added, to stop the reaction, boiled at 100°C for 5 min, and kept at room temperature; then 250 μl of water was added and the mixture was centrifuged to obtain a clear supernatant. For each sample, the absorbance of sample was measured against an avoided reagent at the indicated pH and temperature consisted of the same mixture as in the above sample; however, enzymes were added following addition of DNS into the reaction mixture. The absorbance was measured at 540 nm. The activities of the periplasmic fraction and the supernatant of recombinant E. coli were measured by the same procedure. One unit xylanase activity was defined as the amount of enzyme that releases 1 μmol of xylose per min under the assay conditions.

3. Results

3.1. Biochemical Characterization and Carbohydrate-Metabolism Profile of the Isolated Strain

Morphological and biochemical characterization of the xylanase-producing bacterial isolate from the aquarium sediment revealed that the cells were rod shaped, motile, endospore forming, and Gram positive; they reacted positive in catalase, nitrate reduction, urease, and starch hydrolysis but negative in indole production and H2S formation (Table 1).

Table 1
Physiological and biochemical characteristics of isolates AQ1 based on the API 50 CHB system and other tests described in Materials and Methods. (+) presence; (−) absence.

The isolate termed AQ1 grew well at temperatures ranging from 25 to 55°C; it formed smooth, convex colonies, presumably due to slime formation which was enhanced at temperatures above 30°C. According to Bergey's manual of determinative bacteriology [16] it belongs to the genus Bacillus.

Extended physiological and biochemical characterizations performed by making use of the API 50 CHB kit system [17] revealed that two properties differed from the type strain B. subtilis as described in the API manual (N acetyl glucosamine and D-Turanose assimilation, Table 1). Anyway, the APILAB software suggested B. subtilis as the species (with identification level of very good).

3.2. Molecular Identification

To prove and to further confirm the identity of the strain to the species level, the entire 16S rRNA sequence was determined (GenBank accession number FJ644629). When compared to other 16S rRNA sequences the strain displayed 99% identity with B. subtilis EDR4 as depicted in the phylogenetic tree analysis shown in Figure 1(b). Thus, there is convincing morphological and molecular evidence that isolate AQ1 belongs to the species B. subtilis.

Figure 1
The morphology of newly isolated strain AQ1. Colony morphology on LB xylan agar medium (a) and its phylogenetic tree analyses (b).

3.3. Xylanase Gene Amplification, Cloning, and Sequencing

As outlined in Materials and Methods, a gene of strain AQ1 coding for a family 11 xylanase (xyn) including its indigenous promoter was amplified by PCR, cloned, and sequenced. For the primer designing, we predicted the region that might contain a native promoter based on the B. subtilis strain 168 using promoter prediction tools (available at and found that 110 bp of upstream region in this Bacillus may have a putative promoter with possibility level of 90%. Using the designed primers based on this sequence, we succeeded in cloning and isolating the AQ1 endoxylanase gene. The DNA sequence comprises a 101 bp putative promoter region and the 642 bp spanning ORF starting with the standard initiation codon and ending with a stop codon. The obtained sequence has been submitted to GenBank (accession number FJ644630). The Shine-Dalgarno (SD) sequence strictly matches with the consensus; however, the putative sequence that is strictly similar to −10 and −35 sequence could not be found (Figure 2(a)). This made denomination of a promoter of AQ1 xylanase gene by making use of the same prediction program stay only at the 50% level.

Figure 2
Alignment of AQ1 endoxylanase with other endoxylanases. (a) Comparison of putative promoter region endoxylanase gene of B. subtilis strain AQ1 and that of B.subtilis strain DB104. Underlined nucleotides correspond to the putative SD site, the large alphabet ...

The predicted amino acid sequence contains a putative signal peptide as suggested by the corresponding program ( and shown in Figure 2(b); it comprises the first 28 amino acids at N-terminal.

As mentioned above, primers used for amplification were derived from the genome sequence of B. subtilis strain 168. For comparison, the xyn gene from a strain 168's derivative, namely, B. subtilis DB104 that has exactly the same DNA sequence of endoxylanase gene as that of parent, was also cloned, expressed, and analyzed including its putative native promoter region. The degree of identity of the AQ1 endoxylanase gene including its indigenous promoter was 91% at the nucleotide level, for the predicted protein it was 95% compared to that of B. subtilis strain DB104. The promoter region in the upstream region of AQ1 endoxylanase gene was 9 bp shorter than that of DB104 one (Figure 2(a)).

The comparison between AQ1 recombinant endoxylanase and DB104 one showed that these deduced amino acids were 10 different amino acids, 4 amino acids in signal peptide, and 6 amino acids in assumed mature protein, namely at position 7, 13, 16, 21, 30, 43, 150, 171, 197, and 203 (Figure 2(b)).

3.4. Assay of Enzyme Activities on Agar Plates

The clearing zones of colony spot of recombinant E. coli with AQ1 endoxylanase (AQ1xyn+promoter) were larger than those of the other one with DB104 endoxylanase (DB104xyn+promoter) (Figure 3(a)), showing that qualitatively the endoxylanase activity of AQ1 recombinant endoxylanase might be higher than that of DB104. This result was supported by the measurement data of comparison of the activity of these recombinant enzymes, revealing that the productivity of recombinant E. coli (AQ1xyn+promoter) after 24 hours of cultivation was the highest among those of native endoxylanases resources and another recombinant E. coli (DB104xyn+promoter) (Table 2). This 24-hour period of cultivation is the optimum time in producing the highest specific activity for native AQ1 and DB104 strain (data not shown).

Figure 3Figure 3
Recombinant E. colis with and without xylanase activity and the comparison of properties of AQ1 and DB104 recombinant xylanase. (a) Recombinant E. colis on LB xylan, recombinant E.coli harbouring empty pGEM-T-easy vector (1), recombinant E.coli with vector ...
Table 2
Comparison of the activity at 55°C pH 7 of the supernatant from the fermentation broth after 24 hours of cultivation at 37°C in the different medium content of B.  subtilis AQ1, B.  subtilis DB104, and recombinant ...

3.5. Extracellular Endoxylanases Expression in Native Strains and in Recombinant E. coli and Comparison of Properties of the Recombinant Gene Products

The endoxylanase specific activity at 55°C of the wild-type bacterium of B. subtilis AQ1 after 24-hour cultivation at 37°C was 306.2 ± 4.2 and 529.7 ± 5.6 U/mg in LB and LB with 1% Oat spelt-xylan, respectively (Table 2). Thus, in the original resource the endoxylanase activity appeared to be constitutively expressed but it was clearly enhanced in medium containing xylan. The same phenomenon also occurred in DB104 endoxylanase resource.

The expression of both AQ1 and DB104 endoxylanase gene from its own promoter in E. coli was possible; the recombinant E. coli also displayed a constitutive enzyme activity as to be seen from halo formation around the colony on xylan-supplemented LB agar plates incubated overnight at 37°C (Figure 3(a)). The extracellular activity in both LB and LB-xylan medium of AQ1 and DB104 recombinant endoxylanase were measured in different temperature and pH, and compared. We found that, the clearing zone analyses of recombinant E. coli were consistent with the comparison of the activity of recombinant extracellular AQ1 endoxylanase and DB104 endoxylanase. Extracellular AQ1 recombinant endoxylanase is always higher than the DB104 one. The volumetric and specific activities of extracellular recombinant AQ1 xylanase were 586.9 ± 13.9 U/mL (2173.6 ± 51.4 U/mg) and 823.6 ± 3.5 U/mL (2745.3 ± 11 U/mg) in LB and LB with1% oat spelt xylan, respectively (Table 2), thus, clearly exceeding enzyme activities of the original strain and also DB104 recombinant endoxylanase. Similar to the phenomenon in the original resource, the recombinant endoxylanase activity in E. coli also appeared to be constitutively expressed and it was also enhanced in medium containing xylan.

The comparison of pH and temperature profile and thermostability of AQ1 extracellular recombinant endoxylanase and DB104 one was shown at Figures 3(c), 3(d), and 3(e). The significant difference between AQ1 recombinant endoxylanase and DB104 one is in the higher activity of this AQ1 recombinant endoxylanase—both specific and volumetric activity. The optimal pH and temperature for recombinant endoxylanase AQ1 and DB104 were almost similar, for AQ1 recombinant gene product optimal pH and temperature were pH 6-7 and 55–60°C, respectively, whereas for DB104 were pH 6-7 and 55°C, respectively (Figures 3(c) and 3(d)).

AQ1 recombinant xylanase seemed relatively more stable than DB104 one, for instance, after 30 minutes of incubation at 50°C it still retained its 52% activity compared to 29% residual activity of DB104 recombinant endoxylanase (Figure 3(e)).

The apparent molecular mass of AQ1 recombinant endoxylanase is considered to be 21 kDa, as showed in SDS-PAGE electrophoresis the band with this size was intensified with respect to the arabinose concentration used in the culture. This molecular mass of the endoxylanase agreed with the theoretically predicted value calculated for the deduced polypeptide (Figure 3(b)).

3.6. The Distribution of Recombinant Enzymes in Cellular Fractions in E. coli

As outlined in Materials and Methods, cytoplasmic, periplasmic, and extracellular fractions were subjected to the endoxylanase assay, and all of the fractions showed endoxylanase activity. The percentage of total endoxylanase activity of the cytoplasmic fraction in LB grown cells (without xylan) after 16-hour cultivation was rather high, more than 45% (Figure 4). However, when xylan was added to the medium, the extracellular fraction was found to contain the highest amount, and the cytoplasmic and periplasmic fraction tended to decrease. It seemed that the increase of total endoxylanase activity of supernatant depends on the xylan concentration. For example, after 24 hours of cultivation in LB without xylan, the amount of total activity of supernatant was 14,671 U of whereas the total activity increased to 19,392 and 20,583 U in the presence of 0.1% xylan and 1% xylan, respectively (Figure 4). There was a trend that the increase of total amount of enzyme activity in supernatant culture (out of the cells) was followed by the decrease in cytoplasmic and periplasmic fraction.

Figure 4
Recombinant AQ1 endoxylanase distribution in cellular compartment of E. coli after 16 and 24 hours of cultivation at 37°C of 25 mL medium culture at shaking erlenmeyer flask. The given values in all activity assays are the means of triplicates, ...

4. Discussion

We have successfully isolated a potent xylanolitic bacterium from an Indonesian local habitat. Previously, we have carried out cloning and heterologous expression of an endoxylanase gene from a local Bacillus licheniformis using an E. coli plasmid promoter [8].

In this paper, we report on the cloning and heterologous expression of a family 11 xylanase gene (xyn11) including its indigenous promoter. The gene originating from a new B. subtilis isolate was characterized in detail.

In species determination, 16S rRNA gene sequence comparisons should be performed only in conjunction with phenotypic and phylogenetic properties because distinct species may exist with identical 16S rRNA gene sequences due to the high diversity of members of the B. subtilis species [1820].

Though the endoxylanase-encoding gene and its putative promoter display 91% identity on the nucleic acids level or 95% identity on amino acid level, physiological and phylogenetic analyses assured the species determination; at the same time such divergences clearly delineate B. subtilis AQ1 from the completely sequenced B. subtilis 168 and other totally 14 sequenced representatives belonging to the same species (not shown).

The 101 bp preceding the structural endoxylanase gene, presumably containing the indigenous respective promoter of B.subtilis AQ1, is evidently capable of driving transcription in E. coli since it facilitated the observed very high level of constitutive expression. This promoter region was 9 bp shorter than strain DB104 endoxylanase promoter region. This difference might cause different activity of the endoxylanase produced, since DB104 endoxylanase has lower activity. The detection of such significant levels of endoxylanase activities in the supernatant revealed that the cloned gene and its promoter, and presumably the signal peptide were recognized and it functioned in E. coli, so that it can facilitate the secretion into supernatant.

There was activity of E. coli DH5 α with pGEM-T easy with ORF of AQ1xyn minus promoter region which was grown in LB xylan, but it was insignificant compared to the recombinant with the promoter region. Thus, it is becoming evident that the high level expression of this AQ1 endoxylanase gene in E. coli was caused by the presence of native promoter, although from prediction the probability of the native promoter was only 50%.

The properties of the AQ1 and DB104 such as optimal pH and temperature are nearly the same; however the activity—both volumetric and specific activity—of AQ1 recombinant xylanase was higher. The thermostability of AQ1 recombinant xylanase was also relatively higher at 50, 55, and 60°C. The result suggested that 6 amino acid differences between AQ1 and DB104 xylanase in mature protein might contribute to this difference in thermostability. At the previous study, using direct evolution method it needed only 3 mutations in mature protein to improve the thermal stability of endoxylanase [21]. In fact, the concentration of AQ1 recombinant xylanase was also higher than that of DB104 that might also contribute to its higher thermal stability.

There was another paper reporting the cloning of xylanase gene from B. subtilis [12]. Different to our result, this recombinant endoxylanase gene was expressed in E. coli with the highest endoxylanase activities being located in the periplasmic fraction [12]. We obtained the highest endoxylanase levels in the supernatant, especially in the presence of xylan, possibly due to extended lyses of cells which may suffer from massive secretion of the enzyme to the periplasmic space eventually resulting in disintegration of the cell envelope.

The secretion into culture medium although without xylan was also reported by Ruller et al. 2006 [22]. Compared to the above study where they gained 216,000 U from 1 litre LB after 48 hours at 37°C, we obtained 20,583 U of recombinant endoxylanase in culture supernatant from 25 mL medium in less than 48 hours. It is noteworthy to state, however, that we—other than Ruller et al. 2006—supplemented the LB medium with xylan in laboratory scale.

The example secretion of hydrolytic enzymes mannanase, chitinase, and alpha amylase originated from Bacillus sp. into culture medium using native signal peptide but utilizing T7 promoter in E. coli as a host was also reported by Yamabhai et al. 2008 [23].

The total activity of the supernatant fraction of the recombinant endoxylanase producer increased when xylan was added; however, the activities in the cytoplasmic and in the periplasmic fraction decreased. As the induction of B.subtilis degradative enzymes is subject to gene regulation [24] which differs significantly from that in the Gram negative cloning host, the molecular basis or the reasons of such phenomenon is not yet understood and needs to be elucidated. A possible explanation might come from the secretion stress along with the concomitantly occurring osmotic pressure in xylan-containing media acting on the Gram negative host cells which eventually may lead to the breakdown of the cell wall and the outer membrane, finally releasing the enzyme to the environment (supernatant). Anyway, irrespective of the mechanisms the addition of substrate xylan significantly increased the yield and thus can be applied for obtaining high endoxylanase activity in the culture supernatant. It needs to be elucidated, however, whether cost-effective and naturally available xylan-rich media can similarly be used for production purposes.

Apart from the specific application for xylanase production, the promoter region and signal peptide of this particular gene might be also applied for constitutive extracellular expression of other enzyme genes to such high level.

5. Conclusion

The endoxylanase gene including its indigenous promoter from newly isolated B.subtilis AQ1 strain has been cloned and expressed, and the gene product was secreted into supernatant of culture medium at high level. The AQ1 endoxylanase native promoter was 9 bp shorter than that of B. subtilis DB104 and its ORF had 95% homology at amino acid level with the last mentioned. The specific and volumetric activity of this recombinant enzymes was very high exceeding that of the recombinant DB104 endoxylanase. The presence of xylan increased the amount of enzymes secreted to the medium. This research showed the feasibility of E. coli as a host to produce heterologous extracellular enzymes gene using this AQ1 xylanase promoter and signal peptide.


Part of the work was done in the laboratory of Professor Dr. Friedhelm Meinhardt, Institute for Molecular Microbiology and Biotechnology, University of Münster, Germany in the framework of the Indonesian-Germany (IG) Biotech program (BMBF Grant no. 0315283). A DAAD Research Stay Fellowship 2008 was granted to I. Helianti. The Incentive Research Grant from Indonesian Ministry of Research and Technology 2010 granted to I. Helianti supported the publication. The authors thank Dr. Michael Larsen from the Meinhardt group for assistance in 16S rDNA sequence determination and Dr. Cornelia Koob, Hamburg University, for her help in analyzing the API Test results.


1. Muksin. Pengolahan material serat alami menggunakan enzim mikrobiologi untuk media ekspresi seni dua dimensi. Journal of Visual Art. 2007;1:401–416. (Indonesian)
2. Kulkarni N, Shendye A, Rao M. Molecular and biotechnological aspects of xylanases. FEMS Microbiology Reviews. 1999;23(4):411–456. [PubMed]
3. Beg QK, Kapoor M, Mahajan L, Hoondal GS. Microbial xylanases and their industrial applications: a review. Applied Microbiology and Biotechnology. 2001;56(3-4):326–338. [PubMed]
4. Vázquez MJ, Alonso JL, Domínguez H, Parajó JC. Xylooligosaccharides: manufacture and applications. Trends in Food Science and Technology. 2001;11(11):387–393.
5. Subramaniyan S, Prema P. Biotechnology of microbial xylanases: enzymology, molecular biology, and application. Critical Reviews in Biotechnology. 2002;22(1):33–64. [PubMed]
6. Henrissat B. A classification of glycosyl hydrolases based on amino acid sequence similarities. Biochemical Journal. 1991;280(2):309–316. [PubMed]
7. Oakley AJ, Heinrich T, Thompson CA, Wilce MCJ. Characterization of a family 11 xylanase from Bacillus subtillis B230 used for paper bleaching. Acta Crystallographica D. 2003;59(4):627–636. [PubMed]
8. Helianti I, Nurhayati N, Wahyuntari B. Cloning, sequencing, and expression of a β-1,4-endoxylanase gene from Indonesian Bacillus licheniformis strain I5 in Escherichia coli. World Journal of Microbiology and Biotechnology. 2008;24(8):1273–1279.
9. Lee TH, Lim PO, Lee Y-E. Cloning, characterization, and expression of xylanase A gene from Paenibacillus sp. DG-22 in Escherichia coli. Journal of Microbiology and Biotechnology. 2007;17(1):29–36. [PubMed]
10. Sambrook J, Russell DW. Molecular Cloning: A Laboratory Manual. 3rd edition. Cold Spring Harbor, NY, USA: Cold Spring Harbor Laboratory Press; 2001.
11. Thompson JD, Higgins DG, Gibson TJ. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Research. 1994;22(22):4673–4680. [PMC free article] [PubMed]
12. Huang J, Wang G, Xiao L. Cloning, sequencing and expression of the xylanase gene from a Bacillus subtilis strain B10 in Escherichia coli. Bioresource Technology. 2006;97(6):802–808. [PubMed]
13. Bradford MM. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein dye binding. Analytical Biochemistry. 1976;72(1-2):248–254. [PubMed]
14. Miller GL. Use of dinitrosalycylic acid as reagent for the determination of reducing sugars. Analytical Chemistry. 1959;31:208–218.
15. Bailey MJ, Biely P, Poutanen K. Interlaboratory testing of methods for assay of xylanase activity. Journal of Biotechnology. 1992;23(3):257–270.
16. Holt JG, et al., editors. Bergey’s Manual of Determinative Bacteriology. Baltimore, Md, USA: William & Wilkins; 1994.
17. Logan NA, Berkeley RCW. Identification of Bacillus strains using the API system. Journal of General Microbiology. 1984;130(7):1871–1882. [PubMed]
18. Blackwood KS, Turenne CY, Harmsen D, Kabani AM. Reassessment of sequence-based targets for identification of Bacillus species. Journal of Clinical Microbiology. 2004;42(4):1626–1630. [PMC free article] [PubMed]
19. Nakamura LK, Roberts MS, Cohan FM. Relationship of Bacillus subtilis clades associated with strains 168 and W23: a proposal for Bacillus subtilis subsp. subtilis subsp. nov. and Bacillus subtilis subsp. spizizenii subsp. nov. International Journal of Systematic Bacteriology. 1999;49(3):1211–1215. [PubMed]
20. Porwal S, Lal S, Cheema S, Kalia VC. Phylogeny in aid of the present and novel microbial lineages: diversity in Bacillus. PLoS One. 2009;4(2, article e4438) [PMC free article] [PubMed]
21. Miyazaki K, Takenouchi M, Kondo H, Noro N, Suzuki M, Tsuda S. Thermal stabilization of Bacillus subtilis family-11 xylanase by directed evolution. Journal of Biological Chemistry. 2006;281(15):10236–10242. [PubMed]
22. Ruller R, Rosa JC, Faça VM, Greene LJ, Ward RJ. Efficient constitutive expression of Bacillus subtilis xylanase A in Escherichia coli DH5α under the control of the Bacillus BsXA promoter. Biotechnology and Applied Biochemistry. 2006;43(1):9–15. [PubMed]
23. Yamabhai M, Emrat S, Sukasem S, Pesatcha P, Jaruseranee N, Buranabanyat B. Secretion of recombinant Bacillus hydrolytic enzymes using Escherichia coli expression systems. Journal of Biotechnology. 2008;133(1):50–57. [PubMed]
24. Tjalsma H, Bolhuis A, Jongbloed JDH, Bron S, van Dijl JM. Signal peptide-dependent protein transport in Bacillus subtilis: a genome-based survey of the secretome. Microbiology and Molecular Biology Reviews. 2000;64(3):515–547. [PMC free article] [PubMed]

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