Cloning of a second xylanase-encoding gene of Streptomyces lividans 66

Substrate Recognition and Specificity of Chitin Deacetylases and Related Family 4 Carbohydrate Esterases

Carbohydrate esterases family 4 (CE4 enzymes) includes chitin and peptidoglycan deacetylases, acetylxylan esterases, and poly-N-acetylglucosamine deacetylases that act on structural polysaccharides, altering their physicochemical properties, and participating in diverse biological functions. Chitin and peptidoglycan deacetylases are not only involved in cell wall morphogenesis and remodeling in fungi and bacteria, but they are also used by pathogenic microorganisms to evade host defense mechanisms. Likewise, biofilm formation in bacteria requires partial deacetylation of extracellular polysaccharides mediated by poly-N-acetylglucosamine deacetylases. Such biological functions make these enzymes attractive targets for drug design against pathogenic fungi and bacteria. On the other side, acetylxylan esterases deacetylate plant cell wall complex xylans to make them accessible to hydrolases, making them attractive biocatalysts for biomass utilization. CE4 family members are metal-dependent hydrolases. They are highly specific for their particular substrates, and show diverse modes of action, exhibiting either processive, multiple attack, or patterned deacetylation mechanisms. However, the determinants of substrate specificity remain poorly understood. Here, we review the current knowledge on the structure, activity, and specificity of CE4 enzymes, focusing on chitin deacetylases and related enzymes active on N-acetylglucosamine-containing oligo and polysaccharides.

pspA overexpression in Streptomyces lividans improves both Sec- and Tat-dependent protein secretion

Streptomyces is an interesting host for the secretory production of recombinant proteins because of its innate capacity to secrete proteins at high level in the culture medium. In this report, we evaluated the importance of the phage-shock protein A (PspA) homologue on the protein secretion yield in Streptomyces lividans. The PspA protein is supposed to play a role in the maintenance of the proton motive force (PMF). As the PMF is an energy source for both Sec- and Tat-dependent secretion, we evaluated the influence of the PspA protein on both pathways by modulating the pspA expression. Results indicated that pspA overexpression can improve the Tat-dependent protein secretion as illustrated for the Tat-dependent xylanase C and enhanced green fluorescent protein (EGFP). The effect on Sec-dependent secretion was less pronounced and appeared to be protein dependent as evidenced by the increase in subtilisin inhibitor (Sti-1) secretion but the lack of increase in human tumour necrosis factor (hTNFalpha) secretion in a pspA-overexpressing strain.

Primary metabolism and its control in streptomycetes: a most unusual group of bacteria

Streptomycetes are Gram-positive bacteria with a unique capacity for the production of a multitude of varied and complex secondary metabolites. They also have a complex life cycle including differentiation into at least three distinct cell types. Whilst much attention has been paid to the pathways and regulation of secondary metabolism, less has been paid to the pathways and the regulation of primary metabolism, which supplies the precursors. With the imminent completion of the total genome sequence of Streptomyces coelicolor A3(2), we need to understand the pathways of primary metabolism if we are to understand the role of newly discovered genes. This review is written as a contribution to supplying these wants. Streptomycetes inhabit soil, which, because of the high numbers of microbial competitors, is an oligotrophic environment. Soil nutrient levels reflect the fact that plant-derived material is the main nutrient input; i.e. it is carbon-rich and nitrogen- and phosphate-poor. Control of streptomycete primary metabolism reflects the nutrient availability. The variety and multiplicity of carbohydrate catabolic pathways reflects the variety and multiplicity of carbohydrates in the soil. This multiplicity of pathways has led to investment by streptomycetes in pathway-specific and global regulatory networks such as glucose repression. The mechanism of glucose repression is clearly different from that in other bacteria. Streptomycetes feed by secreting complexes of extracellular enzymes that break down plant cell walls to release nutrients. The induction of these enzyme complexes is often coordinated by inducers that bear no structural relation to the substrate or product of any particular enzyme in the complex; e.g. a product of xylan breakdown may induce cellulase production. Control of amino acid catabolism reflects the relative absence of nitrogen catabolites in soil. The cognate amino acid induces about half of the catabolic pathways and half are constitutive. There are reduced instances of global carbon and nitrogen catabolite control of amino acid catabolism, which again presumably reflects the relative rarity of the catabolites. There are few examples of feedback repression of amino acid biosynthesis. Again this is taken as a reflection of the oligotrophic nature of the streptomycete ecological niche. As amino acids are not present in the environment, streptomycetes have rarely invested in feedback repression. Exceptions to this generalization are the arginine and branched-chain amino acid pathways and some parts of the aromatic amino acid pathways which have regulatory systems similar to Escherichia coli and Bacillus subtilis and other copiotrophic bacteria.

Partial characterization of the Streptomyces lividans xlnB promoter and its use for expression of a thermostable xylanase from Thermotoga maritima

Xylanase activity assays were used to screen a Streptomyces coelicolor genomic library in Escherichia coli, and a xylanase gene that is 99% identical to the xylanase B gene (xlnB) of S. lividans (GenBank accession no. M64552) was identified. The promoter region of this gene was identified by using a transcriptional fusion between the upstream region of the S. coelicolor xlnB gene and the xylE reporter gene. Transcription from the xlnB promoter was found to be induced by xylan and repressed by glucose. A single apparent transcription start site was identified by both primer extension analysis and in vitro run off transcription assays. Analysis of deletions of the promoter identified a region required for glucose repression. By using the transcriptional and protein localization signals of the Streptomyces xlnB gene, an in-frame translational fusion between the end of the xlnB signal sequence and the ATG of the Thermotoga maritima xynA gene was constructed. The xynA gene encodes a thermostable xylanase that has been demonstrated to be useful in the bleaching of Kraft pulp. The xlnB-xynA gene fusion was expressed in Streptomyces, and the activity of the protein produced was thermostable and was localized to the supernatant fraction of harvested cells.

Purification and characterization of an acetyl xylan esterase produced by Streptomyces lividans

The acetyl xylan esterase cloned homologously from Streptomyces lividans [Shareck, Biely, Morosoli and Kluepfel (1995) Gene 153, 105-109] was purified from culture filtrate of the overproducing strain S. lividans IAF43. The secreted enzyme had a molecular mass of 34 kDa and a pI of 9.0. Under the assay conditions with chemically acetylated birchwood xylan the kinetic constants of the enzyme were: specific activity, 715 units/mg, Km 7.94 mg/ml and Vmax 1977 units/mg. Optimal enzyme activity was obtained at 70 degrees C and pH 7.5. Hydrolysis assays with different acetylated substrates showed that the enzyme is specific for deacetylating the O-acetyl group of polysaccharides and is devoid of N-deacetylation activity. Sequential hydrolysis shows that its action is essential for the complete degradation of acetylated xylan by the xylanases of S. lividans.

Analysis of DNA flanking the xlnB locus of Streptomyces lividans reveals genes encoding acetyl xylan esterase and the RNA component of ribonuclease P

Nucleotide sequencing revealed the gene (axeA) encoding acetyl xylan esterase (AxeA) downstream from xlnB in the Streptomyces lividans DNA insert of plasmid pIAF42. AxeA consists of a catalytic- and a substrate-binding domain separated by a Gly-rich linker. The N terminus showed no significant homology with published esterases and acetyl xylan esterases, but some homology was found with the xylanases XylA and XylD and the NodB protein of Rhizobium species which is involved in the biosynthesis of root nodulation factors. The C terminus of AxeA is highly homologous to the C-termini of xylanases XlnB and TFXA, corresponding to the xylan-binding domain of these enzymes. Furthermore, the RNaseP RNA component was found immediately upstream from xlnB gene.

Production and secretion of proteins by streptomycetes

Streptomycetes produce a large number of extracellular enzymes as part of their saprophytic mode of life. Their ability to synthesize enzymes as products of their primary metabolism could lead to the production of many proteins of industrial importance. The development of high-yielding expression systems for both homologous and heterologous gene products is of considerable interest. In this article, we review the current knowledge on the various factors that affect the production and secretion of proteins by streptomycetes and try to evaluate the suitability of these bacteria for the large-scale production of proteins of industrial importance.

Effects of disruption of xylanase-encoding genes on the xylanolytic system of Streptomyces lividans

Wild-type Streptomyces lividans produced the three xylanases (XlnA, XlnB, and XlnC) when xylan, xylan hydrolysates obtained by the action of XlnA, XlnB, and XlnC, or purified small xylo-oligosaccharides (xylobiose [X2], xylotriose [X3], xylotetraose [X4], and xylopentaose [X5]) were used as the carbon source. The three xylanase genes of S. lividans (xlnA, xlnB, and xlnC) were disrupted by using vectors that integrate into the respective genes. Disruption of one or more of the xln genes resulted in reduced growth rates and reduced total xylanase activities when the strain was grown in xylan. The greatest effect was observed when xlnA was disrupted. In medium containing xylan, disruption of xlnA did not affect expression of xlnB and xlnC; disruption of xlnB did not affect expression of xlnA but affected expression of xlnC; and disruption of xlnC did not affect expression of xlnA but affected expression of xlnB. A fraction of XlnB or XlnC hydrolytic products (those with a degree of polymerization greater than 11 [X11]) was found to stimulate expression of xlnB and xlnC in strains disrupted in xlnC and xlnB, respectively, whereas lower-molecular-weight fractions as well as purified small xylo-oligosaccharides did not. The stimulating molecule(s) lost its effect when it was hydrolyzed further by XlnA. A mechanism of transglycosylation reactions by the S. lividans xylanases is postulated to be involved in the regulation of xln genes.

Purification and characterization of the CelB endoglucanase from Streptomyces lividans 66 and DNA sequence of the encoding gene

The endoglucanase CelB isolated from culture filtrates of Streptomyces lividans IAF9 has an M(r) of 36,000. With carboxymethyl cellulose as the substrate, the Vmax and Km values are 110 IU/mg of enzyme and 1.3 mg/ml, respectively. Comparison of primary amino acid sequences classifies CelB in the H family of cellulases.

Beta-mannanase of Streptomyces lividans 66: cloning and DNA sequence of the manA gene and characterization of the enzyme

The gene coding for a beta-mannanase was cloned homologously from Streptomyces lividans and its DNA sequence was determined. The fully secreted enzyme was isolated and purified from culture filtrates of the hyperproducing clone S. lividans IAF36 grown in mineral salt media containing galactomannan as the main carbon source. It had a molecular mass of 36 kDa and a specific activity of 876 i.u./mg of protein. Under the assay conditions used, the optimal enzyme activity was obtained at 58 degrees C and a pH of 6.8. The pI was 3.5. The kinetic constants of this mannanase determined with galactomannan as substrate were a Vmax. of 205 i.u./mg of enzyme and a Km of 0.77 mg/ml. Data from SDS/PAGE and Western blotting show that the cloned enzyme was identical to that of the wild-type strain.

Secretion of a Cryptococcus albidus xylanase in Saccharomyces cerevisiae

The xylanase(XLN)-encoding gene(XLN) of Cryptococcus albidus and its cDNA were each inserted into the vector, pVT100, for expression in Saccharomyces cerevisiae. Expression was under the control of either their own promoter or the gene encoding alcohol dehydrogenase (ADH1) promoter. Yeast transformed with plasmids containing the cDNA of the structural XLN gene and the XLN promoter produced active extracellular XLN when grown with galactose as carbon source. However, with glucose as carbon source, XLN was repressed. Using the ADH1 promoter, which is stimulated by glucose, XLN was secreted into the culture medium. In both cases, the secreted 48-kDa enzyme corresponded to the native XLN produced by C. albidus. With the plasmid bearing the genomic XLN gene, there was transcription, but the seven introns interrupting XLN were not spliced out by S. cerevisiae and no enzyme was produced.

Purification and characterization of an endoglucanase from Streptomyces lividans 66 and DNA sequence of the gene

The endoglucanase isolated from culture filtrates of Streptomyces lividans IAF74 was shown to have an Mr of 46,000 and a pI of 3.3. The specific enzyme activity of 539 IU/mg, determined by the reducing assay method on carboxymethyl cellulose, is among the highest reported in the literature. The cellulase showed typical endo-type activity when reacting on oligocellodextrins. Optimal enzyme activity was obtained at 50 degrees C and pH 5.5. The kinetic constants for this endoglucanase, determined with carboxymethyl cellulose as the substrate, were a Vmax of 24.9 IU/mg of enzyme and a Km of 4.2 mg/ml. Activity was found against neither methylumbelliferyl- nor p-nitrophenyl-cellobiopyranoside nor with xylan. The DNA sequence contains one possible reading frame validated by the N terminus of the mature purified protein. However, neither ATG nor GTG starting codons were identified near the ribosome-binding site. A putative TTG codon was found as a good candidate for the start codon. Comparison of the primary amino acid sequence of the endoglucanase of S. lividans revealed that the N terminus contains a bacterial cellulose-binding domain. The catalytic domain at the C terminus showed similarity to endoglucanases from a Bacillus sp. Thus, the endoglucanase CelA belongs to family A of cellulases as described before (N. R. Gilkes, B. Henrissat, D. G. Kilburn, R. C. Miller, Jr., and R. A. J. Warren, Microbiol. Rev. 55:303-315, 1991.

Review of the Streptomyces lividans/vector pIJ702 system for gene cloning

Interest in the biology of the Streptomyces and application of these soil bacteria to production of commercial antibiotics and enzymes has stimulated the development of efficient cloning techniques and a variety of streptomycete plasmid and phage vectors. Streptomyces lividans is routinely employed as a host for gene cloning, largely because this species recognizes a large number of promoters and appears to lack a restriction system. Vector pIJ702 was constructed from a variant of a larger autonomous plasmid and is often used as a cloning vehicle in conjunction with S. lividans. The host range of vector pIJ702 extends beyond Streptomyces spp., and its high copy number has been exploited for the overproduction of cloned gene products. This combination of host and vector has been used successfully to investigate antibiotic biosynthesis, gene structure and expression, and to map various Streptomyces mutants.

Sequences of three genes specifying xylanases in Streptomyces lividans

The entire nucleotide (nt) sequences of three genes (xlnA, xlnB and xlnC) of Streptomyces lividans encoding three distinct xylanases (Xln) have been determined. The nt sequences were confirmed by comparing the deduced amino acid (aa) sequences with the ones derived from the N-terminal aa sequences of the mature purified proteins. The N-terminus of the XlnA showed some homology with either the N-termini or the C-termini of eight other Xln and of two exo-glucanases. The N-terminus of XlnB is homologous to that of XlnC and to Xln of seven other microorganisms.