Molecular cloning, structure, promoters and regulatory elements for transcription of the Bacillus licheniformis encoded regulon for xylose utilization

Development of a strictly regulated xylose-induced expression system in Streptomyces

Background

Genetic tools including constitutive and inducible promoters have been developed over the last few decades for strain engineering in Streptomyces. Inducible promoters are useful for controlling gene expression, however only a limited number are applicable to Streptomyces. The aim of this study is to develop a controllable protein expression system based on an inducible promoter using sugar inducer, which has not yet been widely applied in Streptomyces.

Results

To determine a candidate promoter, inducible protein expression was first examined in Streptomyces avermitilis MA-4680 using various carbon sources. Xylose isomerase (xylA) promoter derived from xylose (xyl) operon was selected due to strong expression of xylose isomerase (XylA) in the presence of d-xylose. Next, a xylose-inducible protein expression system was constructed by investigating heterologous protein expression (chitobiase as a model protein) driven by the xylA promoter in Streptomyces lividans. Chitobiase activity was detected at high levels in S. lividans strain harboring an expression vector with xylA promoter (pXC), under both xylose-induced and non-induced conditions. Thus, S. avermitilis xylR gene, which encodes a putative repressor of xyl operon, was introduced into constructed vectors in order to control protein expression by d-xylose. Among strains constructed in the study, XCPR strain harboring pXCPR vector exhibited strict regulation of protein expression. Chitobiase activity in the XCPR strain was observed to be 24 times higher under xylose-induced conditions than that under non-induced conditions.

Conclusion

In this study, a strictly regulated protein expression system was developed based on a xylose-induced system. As far as we could ascertain, this is the first report of engineered inducible protein expression in Streptomyces by means of a xylose-induced system. This system might be applicable for controllable expression of toxic products or in the field of synthetic biology using Streptomyces strains.

Electronic supplementary material

The online version of this article (10.1186/s12934-018-0991-y) contains supplementary material, which is available to authorized users.

Recombinant production of the antibody fragment D1.3 scFv with different Bacillus strains

Background

Different strains of the genus Bacillus are versatile candidates for the industrial production and secretion of heterologous proteins. They can be cultivated quite easily, show high growth rates and are usually non-pathogenic and free of endo- and exotoxins. They have the ability to secrete proteins with high efficiency into the growth medium, which allows cost-effective downstream purification processing. Some of the most interesting and challenging heterologous proteins are recombinant antibodies and antibody fragments. They are important and suitable tools in medical research for analytics, diagnostics and therapy. The smallest conventional antibody fragment with high-affinity binding to an antigen is the single-chain fragment variable (scFv). Here, different strains of the genus Bacillus were investigated using diverse cultivation systems for their suitability to produce and secret a recombinant scFv.

Results

Extracellular production of lysozyme-specific scFv D1.3 was realized by constructing a plasmid with a xylose-inducible promoter optimized for Bacillus megaterium and the D1.3scFv gene fused to the coding sequence of the LipA signal peptide from B. megaterium. Functional scFv was successfully secreted with B. megaterium MS941, Bacillus licheniformis MW3 and the three Bacillus subtilis strains 168, DB431 and WB800N differing in the number of produced proteases. Starting with shake flasks (150 mL), the bioprocess was scaled down to microtiter plates (1250 µL) as well as scaled up to laboratory-scale bioreactors (2 L). The highest extracellular concentration of D1.3 scFv (130 mg L⁻¹) and highest space–time-yield (8 mg L⁻¹ h⁻¹) were accomplished with B. subtilis WB800N, a strain deficient in eight proteases. These results were reproduced by the production and secretion of a recombinant penicillin G acylase (Pac).

Conclusions

The genus Bacillus provides high potential microbial host systems for the secretion of challenging heterologous proteins like antibody fragments and large proteins at high titers. In this study, the highest extracellular concentration and space–time-yield of a recombinant antibody fragment for a Gram-positive bacterium so far was achieved. The successful interspecies use of the here-designed plasmid originally optimized for B. megaterium was demonstrated by two examples, an antibody fragment and a penicillin G acylase in up to five different Bacillus strains.

Electronic supplementary material

The online version of this article (doi:10.1186/s12934-017-0625-9) contains supplementary material, which is available to authorized users.

Evidence of a plasmid-encoded oxidative xylose-catabolic pathway in Arthrobacter nicotinovorans pAO1

Due to its high abundance, the D-xylose fraction of lignocellulose provides a promising resource for production of various chemicals. Examples of efficient utilization of d-xylose are nevertheless rare, mainly due to the lack of enzymes with suitable properties for biotechnological applications. The genus Arthrobacter, which occupies an ecological niche rich in lignocellulosic materials and containing species with high resistance and tolerance to environmental factors, is a very suitable candidate for finding D-xylose-degrading enzymes with new properties. In this work, the presence of the pAO1 megaplasmid in cells of Arthrobacter nicotinovorans was directly linked to the ability of this microorganism to ferment D-xylose and to sustain longer log growth. Three pAO1 genes (orf32, orf39, orf40) putatively involved in degradation of xylose were identified and cloned, and the corresponding proteins purified and characterized. ORF40 was shown to be a homotetrameric NADP(+)/NAD(+) sugar dehydrogenase with a strong preference for d-xylose; ORF39 is a monomeric aldehyde dehydrogenase with wide substrate specificity and ORF32 is a constitutive expressed transcription factor putatively involved in control of the entire catabolic pathway. Based on analogies with other pentose degradation pathways, a putative xylose oxidative pathway similar to the Weimberg pathway is postulated.

Metabolic engineering of D-xylose pathway in Clostridium beijerinckii to optimize solvent production from xylose mother liquid

Clostridium beijerinckii is an attractive butanol-producing microbe for its advantage in co-fermenting hexose and pentose sugars. However, this Clostridium strain exhibits undesired efficiency in utilizing D-xylose, one of the major building blocks contained in lignocellulosic materials. Here, we reported a useful metabolic engineering strategy to improve D-xylose consumption by C. beijerinckii. Gene cbei2385, encoding a putative D-xylose repressor XylR, was first disrupted in the C. beijerinckii NCIMB 8052, resulting in a significant increase in D-xylose consumption. A D-xylose proton-symporter (encoded by gene cbei0109) was identified and then overexpressed to further optimize D-xylose utilization, yielding an engineered strain 8052xylR-xylT(ptb) (xylR inactivation plus xylT overexpression driven by ptb promoter). We investigated the strain 8052xylR-xylT(ptb) in fermenting xylose mother liquid, an abundant by-product from industrial-scale xylose preparation from corncob and rich in D-xylose, finally achieving a 35% higher Acetone, Butanol and Ethanol (ABE) solvent titer (16.91 g/L) and a 38% higher yield (0.29 g/g) over those of the wild-type strain. The strategy used in this study enables C. beijerinckii more suitable for butanol production from lignocellulosic materials.

Reconstruction of xylose utilization pathway and regulons in Firmicutes

Background

Many Firmicutes bacteria, including solvent-producing clostridia such as Clostridium acetobutylicum, are able to utilize xylose, an abundant carbon source in nature. Nevertheless, homology searches failed to recognize all the genes for the complete xylose and xyloside utilization pathway in most of them. Moreover, the regulatory mechanisms of xylose catabolism in many Firmicutes except Bacillus spp. still remained unclear.

Results

A comparative genomic approach was used to reconstruct the xylose and xyloside utilization pathway and analyze its regulatory mechanisms in 24 genomes of the Firmicutes. A novel xylose isomerase that is not homologous to previously characterized xylose isomerase, was identified in C. acetobutylicum and several other Clostridia species. The candidate genes for the xylulokinase, xylose transporters, and the transcriptional regulator of xylose metabolism (XylR), were unambiguously assigned in all of the analyzed species based on the analysis of conserved chromosomal gene clustering and regulons. The predicted functions of these genes in C. acetobutylicum were experimentally confirmed through a combination of genetic and biochemical techniques. XylR regulons were reconstructed by identification and comparative analysis of XylR-binding sites upstream of xylose and xyloside utilization genes. A novel XylR-binding DNA motif, which is exceptionally distinct from the DNA motif known for Bacillus XylR, was identified in three Clostridiales species and experimentally validated in C. acetobutylicum by an electrophoretic mobility shift assay.

Conclusions

This study provided comprehensive insights to the xylose catabolism and its regulation in diverse Firmicutes bacteria especially Clostridia species, and paved ways for improving xylose utilization capability in C. acetobutylicum by genetic engineering in the future.

Sustained expression of keratinase gene under PxylA and PamyL promoters in the recombinant Bacillus megaterium MS941

The ker gene encoding pre-pro keratinase of Bacillus licheniformis MKU3 was cloned with xylose inducible promoter (PxylA) or alpha-amylase promoter (PamyL) or both in Escherichia coli-Bacillus shuttle vector, pWH1520 generating recombinant plasmids pWHK3, pWAK3 and pWXAK3 respectively. Compared with Bacillius megaterium MS941 (pWXAK3) expressing ker gene with PxylA-PamyL promoters, B. megaterium MS941 (pWAK3) with PamyL displayed higher keratinase yield (168.6 U/ml) and specific activity (14.59 U/mg) after 36 h of growth in LB medium, however the keratinase yield decreased in the culture grown in LB medium supplemented with starch or xylose or both. A maximum yield of 186.3 U/ml with specific activity of 17.25 U/mg was obtained from xylose induced keratinase expression in B. megaterium MS941 (pWHK3) grown for 24h. The recombinant plasmids were stably maintained with sustained expression of keratinase for about 60 generations in B. megaterium MS941 rather than in B. megaterium 1,4945.

Genetic analysis of a novel pathway for D-xylose metabolism in Caulobacter crescentus

Genetic data suggest that the oligotrophic freshwater bacterium Caulobacter crescentus metabolizes D-xylose through a pathway yielding alpha-ketoglutarate, comparable to the recently described L-arabinose degradation pathway of Azospirillum brasilense. Enzymes of the C. crescentus pathway, including an NAD(+)-dependent xylose dehydrogenase, are encoded in the xylose-inducible xylXABCD operon (CC0823-CC0819).

Bivalent cations and amino-acid composition contribute to the thermostability of Bacillus licheniformis xylose isomerase

Comparative analysis of genome sequence data from mesophilic and hyperthermophilic micro-organisms has revealed a strong bias against specific thermolabile amino-acid residues (i.e. N and Q) in hyperthermophilic proteins. The N + Q content of class II xylose isomerases (XIs) from mesophiles, moderate thermophiles, and hyperthermophiles was examined. It was found to correlate inversely with the growth temperature of the source organism in all cases examined, except for the previously uncharacterized XI from Bacillus licheniformis DSM13 (BLXI), which had an N + Q content comparable to that of homologs from much more thermophilic sources. To determine whether BLXI behaves as a thermostable enzyme, it was expressed in Escherichia coli, and the thermostability and activity properties of the recombinant enzyme were studied. Indeed, it was optimally active at 70-72 degrees C, which is significantly higher than the optimal growth temperature (37 degrees C) of B. licheniformis. The kinetic properties of BLXI, determined at 60 degrees C with glucose and xylose as substrates, were comparable to those of other class II XIs. The stability of BLXI was dependent on the metallic cation present in its two metal-binding sites. The enzyme thermostability increased in the order apoenzyme < Mg2+-enzyme < Co2+-enzyme approximately Mn2+-enzyme, with melting temperatures of 50.3 degrees C, 53.3 degrees C, 73.4 degrees C, and 73.6 degrees C. BLXI inactivation was first-order in all conditions examined. The energy of activation for irreversible inactivation was also strongly influenced by the metal present, ranging from 342 kJ x mol(-1) (apoenzyme) to 604 kJ x mol(-1) (Mg2+-enzyme) to 1166 kJ x mol(-1) (Co2+-enzyme). These results suggest that the first irreversible event in BLXI unfolding is the release of one or both of its metals from the active site. Although N + Q content was an indicator of thermostability for class II XIs, this pattern may not hold for other sets of homologous enzymes. In fact, the extremely thermostable alpha-amylase from B. licheniformis was found to have an average N + Q content compared with homologous enzymes from a variety of mesophilic and thermophilic sources. Thus, it would appear that protein thermostability is a function of more complex molecular determinants than amino-acid content alone.

Genetic evidence for a defective xylan degradation pathway in Lactococcus lactis

Genetic and biochemical evidence for a defective xylan degradation pathway was found linked to the xylose operon in three lactococcal strains, Lactococcus lactis 210, L. lactis IO-1, and L. lactis NRRL B-4449. Immediately downstream of the xylulose kinase gene (xylB) (K. A. Erlandson, J.-H. Park, W. El Khal, H.-H. Kao, P. Basaran, S. Brydges, and C. A. Batt, Appl. Environ. Microbiol. 66:3974-3980, 1999) are two open reading frames encoding a mutarotase (xylM) and a xyloside transporter (xynT) and a partial open reading frame encoding a beta-xylosidase (xynB). These are functions previously unreported for lactococci or lactobacilli. The mutarotase activity of the putative xylM gene product was confirmed by overexpression of the L. lactis enzyme in Escherichia coli and purification of recombinant XylM. We hypothesize that the mutarotase links xylan degradation to xylose metabolism due to the anomeric preference of xylose isomerase. In addition, Northern hybridization experiments suggested that the xylM and xynTB genes are cotranscribed with the xylRAB genes, responsible for xylose metabolism. Although none of the three strains appeared to metabolize xylan or xylobiose, they exhibited xylosidase activity, and L. lactis IO-1 and L. lactis NRRL B-4449 had functional mutarotases.

Regulation of carbon catabolism in Bacillus species

The gram-positive bacterium Bacillus subtilisis capable of using numerous carbohydrates as single sources of carbon and energy. In this review, we discuss the mechanisms of carbon catabolism and its regulation. Like many other bacteria, B. subtilis uses glucose as the most preferred source of carbon and energy. Expression of genes involved in catabolism of many other substrates depends on their presence (induction) and the absence of carbon sources that can be well metabolized (catabolite repression). Induction is achieved by different mechanisms, with antitermination apparently more common in B. subtilis than in other bacteria. Catabolite repression is regulated in a completely different way than in enteric bacteria. The components mediating carbon catabolite repression in B. subtilis are also found in many other gram-positive bacteria of low GC content.

Dissolution of xylose metabolism in Lactococcus lactis

Xylose metabolism, a variable phenotype in strains of Lactococcus lactis, was studied and evidence was obtained for the accumulation of mutations that inactivate the xyl operon. The xylose metabolism operon (xylRAB) was sequenced from three strains of lactococci. Fragments of 4.2, 4.2, and 5.4 kb that included the xyl locus were sequenced from L. lactis subsp. lactis B-4449 (formerly Lactobacillus xylosus), L. lactis subsp. lactis IO-1, and L. lactis subsp. lactis 210, respectively. The two environmental isolates, L. lactis B-4449 and L. lactis IO-1, produce active xylose isomerases and xylulokinases and can metabolize xylose. L. lactis 210, a dairy starter culture strain, has neither xylose isomerase nor xylulokinase activity and is Xyl(-). Xylose isomerase and xylulokinase activities are induced by xylose and repressed by glucose in the two Xyl(+) strains. Sequence comparisons revealed a number of point mutations in the xylA, xylB, and xylR genes in L. lactis 210, IO-1, and B-4449. None of these mutations, with the exception of a premature stop codon in xylB, are obviously lethal, since they lie outside of regions recognized as critical for activity. Nevertheless, either cumulatively or because of indirect affects on the structures of catalytic sites, these mutations render some strains of L. lactis unable to metabolize xylose.

Cloning and characterization of transcription of the xylAB operon in Thermoanaerobacter ethanolicus

The genes encoding xylose isomerase (xylA) and xylulose kinase (xylB) from the thermophilic anaerobe Thermoanaerobacter ethanolicus were found to constitute an operon with the transcription initiation site 169 nucleotides upstream from the previously assigned (K. Dekker, H. Yamagata, K. Sakaguchi, and S. Udaka, Agric. Biol. Chem. 55:221-227, 1991) promoter region. The bicistronic xylAB mRNA was processed by cleavage within the 5'-terminal portion of the XylB-coding sequence. Transcription of xylAB was induced in the presence of xylose, and, unlike in all other xylose-utilizing bacteria studied, was not repressed by glucose. The existence of putative xyl operator sequences suggested that xylose utilization is controlled by a repressor-operator mechanism. The T. ethanolicus xylB gene coded for a 500-amino-acid-residue protein with a deduced amino acid sequence highly homologous to those of other XylBs. This is the first report of an xylB nucleotide sequence and an xyLAB operon from a thermophilic anaerobic bacterium.

Regulation of expression of the Lactobacillus pentosus xylAB operon

The xylose cluster of Lactobacillus pentosus consists of five genes, two of which, xylAB, form an operon and code for the enzymes involved in the catabolism of xylose, while a third encodes a regulatory protein, XylR. By introduction of a multicopy plasmid carrying the xyl operator and by disruption of the chromosomal xylR gene, it was shown that L. pentosus xylR encodes a repressor. Constitutive expression of xylAB in the xylR mutant is repressed by glucose, indicating that glucose repression does not require XylR. The xylR mutant displayed a prolonged lag phase compared to wild-type bacteria when bacteria were shifted from glucose to xylose medium. Differences in the growth rate in xylose medium at different stages of growth are not correlated with differences in levels of xylAB transcription in L. pentosus wild-type or xylR mutant bacteria but are positively correlated in Lactobacillus casei with a plasmid containing xylAB. Glucose repression was further investigated with a ccpA mutant. An 875-bp internal fragment of the ccpA gene of L. pentosus was isolated by PCR and used to construct a ccpA knockout mutant. Transcription analysis of L. pentosus xylA showed that CcpA is involved in glucose repression. CcpA was also shown to be involved in glucose repression of the alpha-amylase promoter of Lactobacillus amylovorus by demonstrating that glucose repression of the chloramphenicol acetyltransferase gene under control of the alpha-amylase promoter is strongly reduced in the L. pentosus ccpA mutant strain.

Isolation and characterization of a xylose-dependent promoter from Caulobacter crescentus

An inducible promoter is a useful tool for the controlled expression of a given gene. Accordingly, we identified, cloned, and sequenced a chromosomal locus, xylX, from Caulobacter crescentus which is required for growth on xylose as the sole carbon source and showed that transcription from a single site is dependent on the presence of xylose in the growth medium. P(xylX) promoter activity was determined as a function of the composition of the growth medium both in single copy and on a plasmid using different reporter genes. One hundred micromolar exogenously added xylose was required for maximal induction of P(xylX) in a strain that is unable to metabolize xylose. P(xylX) activity was induced immediately after the addition of xylose and repressed almost completely when xylose was removed from the growth medium. In addition to the strong transcriptional control, the expression of xylX is also regulated on the translational level.

Molecular and industrial aspects of glucose isomerase

Glucose isomerase (GI) (D-xylose ketol-isomerase; EC. 5.3.1.5) catalyzes the reversible isomerization of D-glucose and D-xylose to D-fructose and D-xylulose, respectively. The enzyme has the largest market in the food industry because of its application in the production of high-fructose corn syrup (HFCS). HFCS, an equilibrium mixture of glucose and fructose, is 1.3 times sweeter than sucrose and serves as a sweetener for use by diabetics. Interconversion of xylose to xylulose by GI serves a nutritional requirement in saprophytic bacteria and has a potential application in the bioconversion of hemicellulose to ethanol. The enzyme is widely distributed in prokaryotes. Intensive research efforts are directed toward improving its suitability for industrial application. Development of microbial strains capable of utilizing xylan-containing raw materials for growth or screening for constitutive mutants of GI is expected to lead to discontinuation of the use of xylose as an inducer for the production of the enzyme. Elimination of Co2+ from the fermentation medium is desirable for avoiding health problems arising from human consumption of HFCS. Immobilization of GI provides an efficient means for its easy recovery and reuse and lowers the cost of its use. X-ray crystallographic and genetic engineering studies support a hydride shift mechanism for the action of GI. Cloning of GI in homologous as well as heterologous hosts has been carried out, with the prime aim of overproducing the enzyme and deciphering the genetic organization of individual genes (xylA, xylB, and xylR) in the xyl operon of different microorganisms. The organization of xylA and xylB seems to be highly conserved in all bacteria. The two genes are transcribed from the same strand in Escherichia coli and Bacillus and Lactobacillus species, whereas they are transcribed divergently on different strands in Streptomyces species. A comparison of the xylA sequences from several bacterial sources revealed the presence of two signature sequences, VXW(GP)GREG(YSTAE)E and (LIVM)EPKPX(EQ)P. The use of an inexpensive inducer in the fermentation medium devoid of Co2+ and redesigning of a tailor-made GI with increased thermostability, higher affinity for glucose, and lower pH optimum will contribute significantly to the development of an economically feasible commercial process for enzymatic isomerization of glucose to fructose. Manipulation of the GI gene by site-directed mutagenesis holds promise that a GI suitable for biotechnological applications will be produced in the foreseeable future.

Glucose and glucose-6-phosphate interaction with Xyl repressor proteins from Bacillus spp. may contribute to regulation of xylose utilization

The xyl operons of several gram-positive bacteria are regulated at the level of transcription by xylose-responsive repressor proteins (XylR). In addition, they are catabolite repressed. Here, we describe a mechanism by which glucose metabolism can affect both regulatory mechanisms. Glucose-6-phosphate appeared to be an anti-inducer of xyl operon transcription, since it could compete with xylose in interaction in vitro with XylR from Bacillus subtilis, B. megaterium, and B. licheniformis. On the other hand, glucose was a low-efficiency inactivator of XylR from B. subtilis and B. megaterium and a weak anti-inducer of XylR from B. licheniformis. Thus, the chemical nature of the substituent at C-5 of xylose and the primary structure of XylR determine the effect of these compounds on xyl operon transcription.

Probing the roles of active site residues in D-xylose isomerase

The roles of active site residues His54, Phe94, Lys183, and His220 in the Streptomyces rubiginosus D-xylose isomerase were probed by site-directed mutagenesis. The kinetic properties and crystal structures of the mutant enzymes were characterized. The pH dependence of diethylpyrocarbonate modification of His54 suggests that His54 does not catalyze ring-opening as a general acid. His54 appears to be involved in anomeric selection and stabilization of the acyclic transition state by hydrogen bonding. Phe94 stabilizes the acyclic-extended transition state directly by hydrophobic interactions and/or indirectly by interactions with Trp137 and Phe26. Lys183 and His220 mutants have little or no activity and the structures of these mutants with D-xylose reveal cyclic alpha-D-xylopyranose. Lys183 functions structurally by maintaining the position of Pro187 and Glu186 and catalytically by interacting with acyclic-extended sugars. His220 provides structure for the M2-metal binding site with properties which are necessary for extension and isomerization of the substrate. A second M2 metal binding site (M2') is observed at a relatively lower occupancy when substrate is added consistent with the hypothesis that the metal moves as the hydride is shifted on the extended substrate.

xylA cloning and sequencing and biochemical characterization of xylose isomerase from Thermotoga neapolitana

The xylA gene coding for xylose isomerase from the hyperthermophile Thermotoga neapolitana 5068 was cloned, sequenced, and expressed in Escherichia coli. The gene encoded a polypeptide of 444 residues with a calculated molecular weight of 50,892. The native enzyme was a homotetramer with a molecular weight of 200,000. This xylose isomerase was a member of the family II enzymes (these differ from family I isomerases by the presence of approximately 50 additional residues at the amino terminus). The enzyme was extremely thermostable, with optimal activity above 95 degrees C. The xylose isomerase showed maximum activity at pH 7.1, but it had high relative activity over a broad pH range. The catalytic efficiency (kcat/Km) of the enzyme was essentially constant between 60 and 90 degrees C, and the catalytic efficiency decreased between 90 and 98 degrees C primarily because of a large increase in Km. The T. neapolitana xylose isomerase had a higher turnover number and a lower Km for glucose than other family II xylose isomerases. Comparisons with other xylose isomerases showed that the catalytic and cation binding regions were well conserved. Comparison of different xylose isomerase sequences showed that numbers of asparagine and glutamine residues decreased with increasing enzyme thermostability, presumably as a thermophilic strategy for diminishing the potential for chemical denaturation through deamidation at elevated temperatures.

Promoter analysis and transcriptional regulation of Lactobacillus pentosus genes involved in xylose catabolism

The xyl genes in Lactobacillus pentosus are induced by xylose and repressed by glucose, ribose, and arabinose. Northern blot analysis showed that regulation is mediated at the transcriptional level. Under inducing conditions, two xylA transcripts were detected, a major transcript of 1.5 kb and a minor transcript of 3 kb. The 3 kb transcript also comprises sequences from xylB, suggesting that xylA and xylB are transcribed together. A 1.2 kb xylR transcript was found under inducing and non-inducing conditions. In the presence of xylose, a second xylR transcript (> 7 kb) was detected, which includes sequences from two upstream genes, xylQ and xylP. The transcription start sites for xylA and xylR were mapped by primer extension and S1 nuclease experiments at 42 and 83 nucleotides, respectively upstream of the translation start sites. Induction by xylose of the chloramphenicol acetyltransferase (CAT) gene under control of the xylA promoter, on a multicopy plasmid, was 60 to 80-fold, but only 3 to 10-fold in the presence of glucose and xylose. Expression of CAT under control of the xylR promoter was constitutive at a level tenfold less than that observed under control of the xylA promoter. Sequence analysis suggests the presence of two operator-like elements, one overlapping with the promoter -35 region of xylA and controlling the expression of xylA by binding factors involved in catabolite repression, and a second operator downstream of the promoter -10 region of xylA, which may bind the product of xylR, the repressor.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of xylose utilization in Bacillus licheniformis: Xyl repressor-xyl-operator interaction studied by DNA modification protection and interference

Xylose utilization in Bacillus licheniformis is inducible by xylose. We establish here that the Xyl repressor recognizes and binds an xyl operator sequence located 12 nucleotides downstream from the transcription start site of the xyl operon. DNA-retardation experiments employing xyl regulatory DNA and soluble protein extracts indicate complex formation in the presence of Xyl repressor. Two repressor-operator complexes are distinguished by different gel mobilities. They yield the same in situ copper-phenanthroline footprint. This result suggests that a single xyl operator may be bound by different oligomers of Xyl repressor. Methylation and hydroxyl radical cleavage protection of the xyl operator by Xyl repressor binding and ethylation interference of Xyl repressor binding to the xyl operator reveals symmetrical interaction of the repressor with two half sites of the operator, which show palindromic symmetry and are located on the same side of the B-form DNA structure.

The xylose isomerase-encoding gene (xylA) of Clostridium thermosaccharolyticum: cloning, sequencing and phylogeny of XylA enzymes

The xylose isomerase (XylA)-encoding gene (xylA) of the thermophilic anaerobic bacterium, Clostridium thermosaccharolyticum NCIB 9385, was cloned as a 4.0-kb DNA fragment by complementation of the Escherichia coli xylA mutant strain, DS941. The open reading frame of 1317 bp encoded a protein of 439 amino acids (aa), with a calculated M(r) of 50,236. The gene was preceeded by a typical clostridial Shine-Dalgarno sequence, and was expressed constitutively in the cloning host. Downstream, the clone appeared to carry a xylB gene (encoding xylulokinase) in the same orientation as xylA. Comparison of the deduced aa sequence of the C. thermosaccharolyticum XylA with 18 other XylA showed that this family of proteins was separated into two clusters, one comprising proteins from organisms with G + C-rich DNA, and the other proteins from organisms with a lower G + C composition. Within the second cluster, the XylA of C. thermosaccharolyticum was most closely related to the enzymes from C. thermosulfurogenes (Thermoanaerobacterium thermosulfurigenes) and C. thermohydrosulfuricum (93 and 84% identity, respectively). Analysis of the aligned sequences indicated two signatures (VXW[GP]GREG[YSTA]E and [LIVM]EPKPX]EQ]P) which may be useful in isolation of novel XylA.

An operator binding-negative mutation of Xyl repressor from Bacillus subtilis is trans dominant in Bacillus megaterium

We have selected a Bacillus subtilis 168-borne xylR Ser to Leu mutation at position 41 of the encoded amino acid sequence showing a constitutive expression phenotype for the xyl operon. When cloned on a multi-copy plasmid in a B. megaterium strain harbouring a single-copy xylA-lacZ fusion it leads to derepression of beta-galactosidase expression. Thus, it is trans dominant over the endogenous xylR, indicating that Xyl repressor functions as a multimer. This result also supports the assumption that the mutation is in a putative alpha-helix-turn-alpha-helix operator binding motif of Xyl repressor.

Cloning and expression of the genes for xylose isomerase and xylulokinase from Klebsiella pneumoniae 1033 in Escherichia coli K12

The genes xylA and xylB were cloned together with their promoter region from the chromosome of Klebsiella pneumoniae var. aerogenes 1033 and the DNA sequence (3225 bp) was determined. The gene xylA encodes the enzyme xylose isomerase (XI or XylA) consisting of 440 amino acids (calculated M(r) of 49,793). The gene xylB encodes the enzyme xylulokinase (XK or XylB) with a calculated M(r) of 51,783 (483 amino acids). The two genes successfully complemented xyl mutants of Escherichia coli K12, but no gene dosage effect was detected. E. coli wild-type cells which harbored plasmids with the intact xylAKp 5' upstream region in high copy number (but lacking an active xylB gene on the plasmids) were phenotypically xylose-negative and xylose isomerase and xylulokinase activities were drastically diminished. Deletion of 5' upstream regions of xylA on these plasmids and their substitution by a lac promoter resulted in a xylose-positive phenotype. This also resulted in overproduction of plasmid-encoded xylose isomerase and xylulokinase activities in recombinant E. coli cells.

Cloning and sequencing the Lactobacillus brevis gene encoding xylose isomerase

The gene (xylA) coding for the Lactobacillus brevis xylose isomerase (Xi) has been isolated and its complete nucleotide sequence determined. L. brevis Xi was purified and the N-terminal sequence determined. All attempts to directly clone the intact xylA using a degenerative primer deduced from amino acids (aa) 10-14 were not successful. A fragment coding for the first 462 bp from the 5' end of xylA was isolated by PCR with two primers, one coding for aa M36 to W43 and the second coding for an aa sequence (WGGREG) conserved in a number of Xi's isolated from other bacteria. From the sequence of this fragment, two additional PCR primers were synthesized, which were used in an 'outward' reaction to clone a 546-bp fragment including a region upstream from the N terminus. Finally, the complete xylA gene was cloned in a 0.43-kb NlaIII-SalI fragment and a 1.9-kb SalI-EcoRI fragment. The 449-aa sequence for the L. brevis Xi shows homology with Xis isolated from other bacteria, especially within the primary catalytic domains of the enzyme.

Regulation of Staphylococcus xylosus xylose utilization genes at the molecular level

We have investigated the regulation of the operon encoding xylose utilization in Staphylococcus xylosus C2a and Staphylococcus carnosus TM300. For in vivo studies, transcriptional fusions of the xylAB regulatory region to the lipase gene from Staphylococcus hyicus were constructed. Repression of lipase activity depended on a functional xylR gene and an xyl operator palindrome downstream of the promoter, while induction was obtained in the presence of xylose. Inactivation of either xylR or the xyl operator led to constitutive expression in the absence of xylose. Crude protein extracts from xylR+ staphylococci led to gel mobility shifts of the xyl regulatory DNA in the absence but not in the presence of xylose. A copper-phenanthroline footprint of the shifted band revealed protection of 28 phosphodiesters from cleavage in each strand of the xyl operator. Thus, the Xyl repressor covers the DNA over more than 2.5 helical turns. Glucose repression of the xyl operon occurs at the level of transcription and is independent of a functional xylR gene. A potential cis-active sequence element for glucose repression is discussed on the basis of sequence similarities to respective elements from bacilli.

Molecular cloning, structure, promoters and regulatory elements for transcription of the Bacillus megaterium encoded regulon for xylose utilization

The xylA and xylB genes of Bacillus subtilis BR151 encoding xylose isomerase and xylulokinase, respectively, were disrupted by gene replacement rendering the constructed mutant strain unable to grow on xylose as the sole carbon source. The Bacillus megaterium encoded xyl genes were cloned by complementation of this strain to xylose utilization. The nucleotide sequence of about 4 kbp of the insertion indicates the presence of the xylA and xylB genes on the complementing plasmid. Furthermore, a regulatory gene, xylR, is located upstream of xylA and has opposite polarity to it. The intergenic region between the divergently oriented reading frames of xylR and xylA contains palindromic sequences of 24 bp spaced by five central bp and 29 bp spaced by 11 bp, respectively, and two promoters with opposite orientation as determined by primer extension analysis. They overlap with one nucleotide of their--35 consensus boxes. Transcriptional fusions of lacZ to xylA, xylB and xylR were constructed and revealed that xylA and xylB are repressed in the absence and can be 200-fold induced in the presence of xylose. The increased level of xylAB mRNA in induced and its absence in repressed cells confirms that this regulation occurs on the level of transcription. Deletion of the xylR gene encoding the Xyl repressor results in constitutive expression of xylAB. The transcription of xylR is autoregulated and can be induced 9-fold by xylose. The mechanism of this regulation is not clear. While the apparent xyl operator palindrome is upstream of the xylR promoter, the potential recognition of another palindrome downstream of this promoter by Xyl repressor is discussed.