High-level expression, purification, and characterization of recombinant wheat xylanase inhibitor TAXI-I secreted by the yeast Pichia pastoris

Triticum aestivum xylanase inhibitor I (TAXI-I) is a wheat protein that inhibits microbial xylanases belonging to glycoside hydrolase family 11. In the present study, recombinant TAXI-I (rTAXI-I) was successfully produced by the methylotrophic yeast Pichia pastoris at high expression levels (approximately 75 mg/L). The rTAXI-I protein was purified from the P. pastoris culture medium using cation exchange and gel filtration chromatographic steps. rTAXI-I has an iso-electric point of at least 9.3 and a mass spectrometry molecular mass of 42,013 Da indicative of one N-linked glycosylation. The recombinant protein fold was confirmed by circular dichroism spectroscopy. Xylanase inhibition by rTAXI-I was optimal at 20-30 degrees C and at pH 5.0. rTAXI-I still showed xylanase inhibition activity at 30 degrees C after a 40 min pre-incubation step at temperatures between 4 and 70 degrees C and after 2 h pre-incubation at room temperature at a pH ranging from 3.0 to 12.0, respectively. All tested glycoside hydrolase family 11 xylanases were inhibited by rTAXI-I whereas those belonging to family 10 were not. Specific inhibition activities against family 11 Aspergillus niger and Bacillus subtilis xylanases were 3570 and 2940IU/mg protein, respectively. The obtained biochemical characteristics of rTAXI-I produced by P. pastoris (no proteolytical cleft) were similar to those of natural TAXI-I (mixture of proteolytically processed and non-processed forms) and non-glycosylated rTAXI-I expressed in Escherichia coli. The present results show that xylanase inhibition activity of TAXI-I is only affected to a limited degree by its glycosylation or proteolytic processing.     

Proteinaceous inhibitors of microbial xylanases

At the end of 1990s two structurally different proteinaceous inhibitors of xylanases were discovered in the grain of wheat (Triticum aestivum). They were named TAXI (T. aestivum xylanase inhibitor) and XIP (xylanase-inhibiting protein). Later it was shown that TAXI and XIP in wheat are present in several isoforms encoded by different genes. TAXI- and XIP-like inhibitors have also been found in other cereals-barley, rye, rice, maize, etc. All these proteins can specifically inhibit activity of fungal and bacterial xylanases belonging to families 10 and 11 of glycoside hydrolases, but they do not affect endogenous enzymes produced by plants. A common viewpoint is that the presence of proteinaceous inhibitors in cereals is a response of plants to pathogenic attack by microorganisms. A few years ago, an inhibitor of a third type was discovered in wheat. It was named TLXI (thaumatin-like xylanase inhibitor) because of its similarity to the thaumatin family of plant proteins. In this review, the occurrence of proteinaceous inhibitors of xylanases in different cereals, their specificity towards fungal and bacterial enzymes, as well as structural features responsible for enzyme sensitivity to various types of inhibitors are discussed.     

Xylanases from <Emphasis Type="Italic">Aspergillus niger,Aspergillus niveus</Emphasis> and <Emphasis Type="Italic">Aspergillus ochraceus</Emphasis> produced under solid-state fermentation and their application in cellulose pulp bleaching

This study describes the production of xylanases from Aspergillus niveus, A. niger, and A. ochraceus under solid-state fermentation using agro-industrial residues as substrates. Enzyme production was improved using a mixture of wheat bran and yeast extract or peptone. When a mixture of corncob and wheat bran was used, xylanase production from A. niger and A. ochraceus increased by 18%. All cultures were incubated at 30 °C at 70–80% relative humidity for 96 h. For biobleaching assays, 10 or 35 U of xylanase/g dry cellulose pulp were incubated at pH 5.5 for 1 or 2 h, at 55 °C. The delignification efficiency was 20%, the brightness (percentage of ISO) increased two to three points and the viscosity was maintained confirming the absence of cellulolytic activity. These results indicated that the use of xylanases could help to reduce the amount of chlorine compounds used in cellulose pulp treatment.     

Structural basis for inhibition of Aspergillus niger xylanase by triticum aestivum xylanase inhibitor-I

Plants developed a diverse battery of defense mechanisms in response to continual challenges by a broad spectrum of pathogenic microorganisms. Their defense arsenal includes inhibitors of cell wall-degrading enzymes, which hinder a possible invasion and colonization by antagonists. The structure of Triticum aestivum xylanase inhibitor-I (TAXI-I), a first member of potent TAXI-type inhibitors of fungal and bacterial family 11 xylanases, has been determined to 1.7-A resolution. Surprisingly, TAXI-I displays structural homology with the pepsin-like family of aspartic proteases but is proteolytically nonfunctional, because one or more residues of the essential catalytical triad are absent. The structure of the TAXI-I.Aspergillus niger xylanase I complex, at a resolution of 1.8 A, illustrates the ability of tight binding and inhibition with subnanomolar affinity and indicates the importance of the C-terminal end for the differences in xylanase specificity among different TAXI-type inhibitors.     

Hydrolysis of xylans by a thermostable hybrid xylanase expressed in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Escherichia coli-expressed a hybrid xylanase, Btx, encoded by a designed hybrid xylanase gene btx was purified. The molecular mass of the enzyme was estimated to be 22 kDa. The K _m and k _cat values for Btx were 1.9 mg/ml and 140 s⁻¹, respectively. It hydrolyzed xylan principally to xylobiose and xylotriose, and was functionally similar to family 11 xylanases. As some differences were found in the hydrolytic products between birchwood xylan and wheat bran insoluble xylan, the xylan binding domains in xylanase Btx must have different effects on soluble and insoluble xylan.     

A family 11 xylanase from Penicillium funiculosum is strongly inhibited by three wheat xylanase inhibitors

Steady-state kinetic approaches were used to investigate the binding of a novel Penicillium funiculosum xylanase, XYNC, with three known xylanase inhibitor proteins from wheat (Triticum aestivum). The xylanase gene (xynC) was cloned from a P. funiculosum genomic library and the deduced amino acid sequence of XYNC exhibited high sequence similarity with fungal family 11 xylanases. xynC was overexpressed in P. funiculosum and the product (XYNC: M(r)=23.6 kDa; pI=3.7) purified and shown to efficiently degrade birchwood xylan [K(m)=0.47% w/v, Vmax=2540 micromol xylose min(-1) (mg protein)(-1) at pH 5.5 and 30 degrees C] and soluble wheat arabinoxylans [K(m)=1.45% w/v, Vmax=7190 micromol xylose min(-1) mg protein)(-1) at pH 5.5 and 30 degrees C]. The xylanase activity of XYNC was inhibited strongly by three xylanase inhibitor proteins from wheat; XIP-I, TAXI I and TAXI II. The inhibition for each was competitive, with very tight binding (K(i)=3.4, 16 and 17 nM, respectively) equivalent to free energy changes (deltaG degrees ) of -49, -45 and -45 kJ mol(-1). This is the first report describing a xylanase that is inhibited by all three wheat xylanase inhibitor proteins described to date.     

Production of extracellular enzymes during the solubilisation of straw by Thermomonospora fusca BD25

The production of three extracellular enzymes during the solubilisation of ball-milled wheat straw by seven actinomycete strains, was examined. A general correlation was observed between the production of extracellular enzymes (xylanases, endoglucanases and peroxidases) and the formation of the solubilised lignocellulose intermediate product (APPL), with the thermophilic actinomycete Thermomonospora fusca BD25 exhibiting greatest extracellular enzyme activity and highest APPL production. Production of all three enzymes; endoxylanase, endoglucanase and peroxidase, and lignocellulose solubilisation, occured during primary growth with maximum activity at the end of the exponential phase (48–96 h). The inducibility and stability of extracellular enzymes from T. fusca were further characterised. When xylan replaced ball-milled wheat straw as the growth substrate, reduced enzyme activities were observed (28–96% reduction in enzyme activities), whereas carboxymethylcellulose was found to be a poor inducer of all three enzyme activities (80–100% reduction in enzyme activities). The pH and temperature optima for extracellular enzyme activities from T. fusca was found to be pH 7.0–8.0 and 60°C, respectively. Analysis of concentrated crude supernatant from T. fusca by native polyacrylamide gel electrophoresis revealed the existence of two non-haem peroxidases. The stability of the extracellular lignocellulose-degrading enzymes for T. fusca suggest their suitability for future biotechnological processes such as biobleaching.     

Enhancement of the activity and alkaline pH stability of <Emphasis Type="Italic">Thermobifida fusca</Emphasis> xylanase A by directed evolution

Directed evolution has been used to enhance the catalytic activity and alkaline pH stability of Thermobifida fusca xylanase A, which is one of the most thermostable xylanases. Under triple screened traits of activity, alkaline pH stability and thermostability, through two rounds of random mutagenesis using DNA shuffling, a mutant 2TfxA98 with approximately 12-fold increased k _cat/K _m and 4.5-fold decreased K _m compared with its parent was obtained. Moreover, the alkaline pH stability of 2TfxA98 is increased significantly, with a thermostability slightly lower than that of its parent. Five amino acid substitutions (T21A, G25P, V87P, I91T, and G217L), three of them are near the catalytic active site, were identified by sequencing the genes encoding this evolved enzyme. The activity and stabilizing effects of each amino acid mutation in the evolved enzyme were evaluated by site-directed mutagenesis. This study shows a useful approach to improve the catalytic activity and alkaline pH stability of T. fusca xylanase A toward the hydrolysis of xylan.     

Cloning of the xynNB gene encoding xylanase B from Aspergillus niger and its expression in Aspergillus kawachii

Aspergillus niger IFO 4066 produced two xylanases, xylanase A (XynNA) and xylanase B (XynNB), in culture medium, and these enzymes were purified. Acidophilic xylanase such as xylanase C (XynC) of white koji mold (Aspergillus kawachii IFO 4308) was not detected in A. niger cultures. However, results of Southern analysis using xynC cDNA of A. kawachii as a probe suggested that A. niger contained a gene homologous to xynC of A. kawachii. Therefore, we cloned this xylanase gene from A. niger. The predicted amino acid sequence of the cloned xylanase showed a homology to that of xynC of A. kawachii. However, a large number of amino acid substitutions were detected, especially in the N-terminal region. Both this cloned gene and xynC gene of A. kawachii had an intron at the same position in the coding region. The cloned gene was expressed in A. kawachii and a large quantity of xylanase was produced. The elution profile on an anion exchange chromatogram and the N-terminal amino acid sequence of the xylanase purified from the transformant were the same as those of XynNB. This confirmed that the cloned gene encoded XynNB.     

Addendum to Issue 1 - ENZITEC 2012Simultaneous biosynthesis of biomass-degrading enzymes using co-cultivation of Aspergillus niger and Trichoderma reesei

Abstract

The biotransformation of lignocellulosic materials into biofuels and chemicals requires the simultaneous action of multiple enzymes. Since the cost of producing an efficient enzyme system maybe high, mixed cultures of microorganisms maybe an alternative to increase enzymatic production and consequently reduce costs. This study investigated the effects of different inoculum ratios and inoculation delays on the biosynthesis of cellulases and xylanases during co-cultivation of Aspergillus niger and Trichoderma reesei under solid-state fermentation (SSF). While the monoculture of T. reesei was more efficient for CMCase production than the co-cultivation of A. niger and T. reesei, a significant increase in β-glucosidase and xylanase production was achieved by co-cultivation of both species. The maximum CMCase activity of 153.91 IU/g was obtained with T. reesei after 48 h of cultivation, while the highest β-glucosidase activity of 119.71 IU/g (after 120 h) was obtained by co-cultivation of A. niger and T. reesei with a 3:1 inoculum ratio (A. niger: T. reesei). The greatest xylanase activity observed was 589.39 IU/g after 72 h of mixed culturing of A. niger and T. Reesei with a 1:1 inoculum ratio. This is the first study where the effects of inoculum ratio and inoculation delay in mixed culture of T. reesei and A. niger under SSF have been systematically assessed, and it indicates co-cultivation as a feasible alternative to increase enzymatic production.     

Five mutations in N-terminus confer thermostability on mesophilic xylanase

The termini of a pair of xylanases, one of mesophilic and one of thermophilic origin, was studied by molecular dissection and systematic mutagenesis. The thermostability of the mesophilic xylanase SoxB from Streptomyces olivaceovirdis was significantly improved by substituting its 33 N-terminal amino acid residues with the corresponding residues of the thermophilic xylanase TfxA from Thermomonospora fusca. Five amino acid substitutions, which clustered in one of the regions of the N-terminus, were discovered, for the first time, to account for the majority of the improvement in thermostability of SoxB. Further systematic mutagenesis and analysis of the five mutations demonstrated that comprehensive synergism of the five mutations was involved in conferring the thermostability on the SoxB. Moreover, when the five thermostabilizing mutations were introduced into two other G/11 xylanases, SlxB from Streptomyces lividans and AnxB from Aspergillus niger, their thermostabilities were also dramatically enhanced.     

Molecular identification and chromosomal localization of genes encoding<Emphasis Type="Italic"> Triticum aestivum</Emphasis> xylanase inhibitor I-like proteins in cereals

TAXI (Triticum aestivum xylanase inhibitor) proteins are present in wheat flour and are known to inhibit glycosyl hydrolase family 11 endoxylanases, enzymes which are commonly applied in grain processing. Here, we describe the PCR-based molecular identification of genes encoding endoxylanase inhibitors HVXI and SCXI, the TAXI-like proteins from barley (Hordeum vulgare) and rye (Secale cereale) respectively. The HVXI coding sequence encodes a mature protein of 384 amino acids preceded by a 19 amino acid long signal sequence. SCXI-II/III has an open reading frame encoding a signal peptide of 21 amino acids and a mature protein of 375 amino acids. As for TAXI-I, no introns were detected in the untranslated regions and coding sequences identified. These newly identified sequences allowed us to perform a multiple sequence alignment with TAXI-I and similar proteins. Rice TAXI-type proteins clustered together with the cereal endoxylanase inhibitors. Dicotyledonous proteins with sequence similarity to TAXI-I, including the tomato xyloglucan-specific endoglucanase inhibiting protein, formed a different clade. The TAXI-type proteins may hence be part of a superfamily of proteins all involved in plant responses to biotic or abiotic stress and for which a function as glycosyl hydrolase inhibitors can be suggested. The chromosomal localization of the TAXI-I gene identified on wheat chromosome 3B, of the SCXI-II/III gene identified on rye chromosome 6R, and the presence of a cluster of TAXI-like genes on rice chromosome 1, allowed us to assign the location of TAXI-like genes to the wheat-rye translocation area 3BL/6RL characterized by RFLP markers XGlb33 and Xpsr454 and isozyme Est-5. In rice, RFLP marker C1310S corresponds to a TAXI-like protein encoding sequence.Communicated by P. Langridge     

Cloning of a xylanase gene <Emphasis Type="Italic">xyn2A</Emphasis> from rumen fungus <Emphasis Type="Italic">Neocallimastix</Emphasis> sp. GMLF2 in <Emphasis Type="Italic">Escherichia coli</Emphasis> and its partial characterization

Anaerobic fungi belonging to the family Neocallimastigaceae are native inhabitants in the rumen of the most herbivores, such as cattle, sheep and goats. A member of this unique group, Neocallimastix sp. GMLF2 was isolated from cattle feces and screened for its xylanase encoding gene using polymerase chain reaction. The gene coding for a xylanase (xyn2A) was cloned in Escherichia coli and expression was monitored. To determine the enzyme activity, assays were conducted for both fungal xylanase and cloned xylanase (Xyl2A) for supernatant and cell-associated activities. Optimum pH and temperature of the enzyme were found to be 6.5 and 50°C, respectively. The enzyme was stable at 40°C and 50°C for 20 min but lost most of its activity when temperature reached 60°C for 5-min incubation time. Rumen fungal xylanase was mainly released to the supernatant of culture, while cloned xylanase activity was found as cell-associated. Multiple alignment of the amino acid sequences of Xyl2A with published xylanases from various organisms suggested that Xyl2A belongs to glycoside hydrolase family 11.     

Synergy between xylanases from glycoside hydrolase family 10 and family 11 and a feruloyl esterase in the release of phenolic acids from cereal arabinoxylan

The bioconversion of waste residues (by-products) from cereal processing industries requires the cooperation of enzymes able to degrade xylanolytic and cellulosic material. The type A feruloyl esterase from Aspergillus niger, AnFaeA, works synergistically with (1→4)-β-d-xylopyranosidases (xylanases) to release monomeric and dimeric ferulic acid (FA) from cereal cell wall-derived material. The esterase was more effective with a family 11 xylanase from Trichoderma viride in releasing FA and with a family 10 xylanase from Thermoascus aurantiacus in releasing the 5,5′ form of diferulic acid from arabinoxylan (AX) derived from brewers’ spent grain. The converse was found for the release of the phenolic acids from wheat bran-derived AXs. This may be indicative of compositional differences in AXs in cereals.     

Emergence of a subfamily of xylanase inhibitors within glycoside hydrolase family 18

The xylanase inhibitor protein I (XIP-I), recently identified in wheat, inhibits xylanases belonging to glycoside hydrolase families 10 (GH10) and 11 (GH11). Sequence and structural similarities indicate that XIP-I is related to chitinases of family GH18, despite its lack of enzymatic activity. Here we report the identification and biochemical characterization of a XIP-type inhibitor from rice. Despite its initial classification as a chitinase, the rice inhibitor does not exhibit chitinolytic activity but shows specificities towards fungal GH11 xylanases similar to that of its wheat counterpart. This, together, with an analysis of approximately 150 plant members of glycosidase family GH18 provides compelling evidence that xylanase inhibitors are largely represented in this family, and that this novel function has recently emerged based on a common scaffold. The plurifunctionality of GH18 members has major implications for genomic annotations and predicted gene function. This study provides new information which will lead to a better understanding of the biological significance of a number of GH18 'inactivated' chitinases.     

γ-Conglutin,the Lupinus albus XEGIP-like protein,whose expression is elicited by chitosan,lacks of the typical inhibitory activity against GH12 endo-glucanases

γ-Conglutin, a glycoprotein from Lupinus albus seed, has been characterized at molecular level but its physiological function is still unknown. γ-Conglutin shares a high structural similarity with xyloglucan-specific endo-β-1,4-glucanase inhibitor proteins (XEGIPs) and Triticum aestivum xylanase inhibitor (TAXI-I), which act specifically against fungal glycosyl hydrolase belonging to families 12 and 11, respectively. To assess the possible involvement of γ-conglutin in plant defense, germinating lupin seeds were incubated with chitosan. The relative quantification of γ-conglutin mRNA extracted from cotyledons was then carried out by RT-qPCR and indicated that chitosan strongly elicited the expression of γ-conglutin. Moreover, biochemical trials aimed to test the inhibitory capacity of the protein have been also carried out. γ-Conglutin failed to inhibit representative fungal endo-glucanases and other cell wall-degrading enzymes. To explain the lack of inhibitory capacity we investigated the possible structural differences between γ-conglutin and XEGIPs and TAXI-I, including the construction of a predictive 3D model of the protein. Bioinformatic analysis suggests that the lack of inhibitory activity of γ-conglutin can be attributed to sequence differences in the inhibitor interaction domains, and in particular to a sequence deletion in one of the functional loops.     

Fusarium graminearum xylanases show different functional stabilities,substrate specificities and inhibition sensitivities

When grown on arabinoxylan as the sole carbon source, the cereal phytopathogen Fusarium graminearum expresses four xylanases. Cloning and heterologous expression of the corresponding xylanase encoding genes and analysis of general biochemical properties, substrate specificities and inhibition sensitivities revealed some marked differences. XylA and XylB are glycoside hydrolase family (GH) 11 xylanases, while XylC and XylD belong to GH10. pH and temperature for optimal activity of the enzymes were between 6.0 and 7.0 and 40 °C, respectively. Interestingly, XylC displayed remarkable pH stability as it retained most of its activity even after pre-incubation at pH 1.0 and 13.0 for 120 min at room temperature. All xylanases hydrolysed xylotetraose, xylopentaose and xylohexaose, but to different extents, while only XylC and XylD hydrolysed xylotriose. The two GH10 xylanases released a higher percentage of smaller products from xylan and xylo-oligosaccharides than did their GH11 counterparts. Analysis of kinetic properties revealed that wheat arabinoxylan is the favoured XylC substrate while XylA and XylB prefer sparsely substituted oat spelt xylan. XylC and XylD were inhibited by xylanase inhibiting protein (XIP), while XylA and XylB were sensitive to Triticum aestivum xylanase inhibitor (TAXI). Because of its pH stability and preference for arabinoxylan, XylC is a valuable candidate for use in biotechnological applications.     

Xylanase production by endophytic Aspergillus niger using pentose-rich hydrothermal liquor from sugarcane bagasse

Fungal xylanases have been widely studied and various production methods have been proposed using submerged and solid-state fermentation. This class of enzyme is used to supplement cellulolytic enzyme cocktails in order to enhance the enzymatic hydrolysis of plant cell walls. The present work investigates the production of xylanase and other accessory enzymes by a recently isolated endophytic Aspergillus niger DR02 strain, using the pentose-rich liquor from hydrothermal pretreatment of sugarcane bagasse as carbon source. Batch and fed-batch submerged cultivation approaches were developed in order to minimize the toxicity of the liquor and increase enzyme production. Maximum xylanase activities obtained were 458.1 U/mL for constant fed-batch, 428.1 U/mL for exponential fed-batch, and 264.37 U/mL for pulsed fed-batch modes. The results indicated that carbon-limited fed-batch cultivation can reduce fungal catabolite repression, as well as overcome possible negative effects of toxic compounds present in the pentose-rich liquor. Enzymatic panel and mass spectrometric analyses of the fed-batch A. niger secretome showed high levels of xylanolytic enzymes (GH10, GH11, and GH62 Cazy families), together with cellobiohydrolase (G6 and GH7), β-glucosidase, β-xylosidase (GH3), and feruloyl esterase (CE1) accessory enzyme activities. The yields of glucose and xylose from enzymatic hydrolysis of hydrothermally pretreated sugarcane bagasse increased by 43.7 and 65.3%, respectively, when a commercial cellulase preparation was supplemented with the A. niger DR02 constant fed-batch enzyme complex.     

Molecular identification of wheat endoxylanase inhibitor TAXI-II and the determinants of its inhibition specificity

Wheat grains contain Triticum aestivum xylanase inhibitor (TAXI) proteins which inhibit microbial xylanases, some of which are used in cereal based food industries. These inhibitors may play a role in plant defence. Among the TAXI isoforms described so far, TAXI-II displays a deviating inhibition specificity pattern. Here, we report on the molecular identity of TAXI-II and the basis of its inhibition specificity. Three candidate TAXI-II encoding sequences were isolated and recombinantly expressed in Pichia pastoris. To identify TAXI-II, the resulting proteins were tested against glycoside hydrolase family (GHF) 11 xylanases of Aspergillus niger (ANX) and Bacillus subtilis (BSX). One of these proteins (rTAXI-IB) inhibited both enzymes, like natural TAXI-I. The other candidates (rTAXI-IIA and rTAXI-IIB) showed an inhibition pattern typical for natural TAXI-II, only clearly inhibiting BSX. Comparative analysis of these highly similar sequences with distinct inhibition activity patterns, combined with information on the structural basis for ANX inhibition by TAXI-I [S. Sansen, C.J. De Ranter, K. Gebruers, K. Brijs, C.M. Courtin, J.A. Delcour, A. Rabijns, Structural basis for inhibition of Aspergillus niger xylanase by Triticum aestivum xylanase inhibitor-I, J. Biol. Chem. 279 (2004) 36022-36028], indicated a crucial role for Pro294 of TAXI-IIA and Gln376 of TAXI-IIB in determining the reduced inhibition activity towards ANX. Consequently, single point mutants rTAXI-IIA[P294L] and rTAXI-IIB[Q376H], both displaying the Leu/His combination corresponding to TAXI-I, were able to inhibit ANX. These results show that TAXI-II inhibition specificity bears on the identity of two key residues at positions 294 and 376, which are involved in the interaction at the -2 glycon subsite and the active site of GHF 11, respectively.