Improved native affinity purification of RNA

RNA biochemical or structural studies often require an RNA sample that is chemically pure, and most protocols for its in vitro production use denaturing polyacrylamide gel electrophoresis to achieve this. Unfortunately, many RNAs do not quantitatively refold into an active conformation after denaturation, creating significant problems for downstream characterization or use. In addition, this traditional purification method is not amenable to studies demanding high-throughput RNA production. Recently, we presented the first general method for producing almost any RNA sequence that employs an affinity tag that is removed during the purification process. Because technical difficulties prevented application of this method to many RNAs, we have developed an improved version that utilizes a different activatable ribozyme and affinity tag that are considerably more robust, rapid, and broadly applicable.     

链霉菌Strz-6木聚糖酶的纯化和固定化研究

链霉菌胞外木聚糖酶经过盐析、离子交换和分子筛层析纯化,粗酶液被纯化了32.5倍,比活力达498u/mg,活力回收46.6%。纯化后的酶固定在戊二醛交联的壳聚糖上,酶活回收率为42.8%。固定化酶的最适pH为6.0,最适温度为60℃,且固定化酶在65~75℃活力都较高。该酶的耐热性比较强,固定化酶热稳定性优于原酶;以木聚糖为底物,固定化酶的表观米氏常数为0.93×10-2g/L。     

Structure-based engineering of glucose specificity in a family 10 xylanase from Streptomyces olivaceoviridis E-86

Substrate specificity is one of the most important functional property of enzymes. We use family 10 xylanase from Streptomyces olivaceoviridis as a model for substrate specificity of glycoside hydrolases. Seven variants were initially designed to change the preference from xylose to glucose at substrate binding subsites ?2 and ?1. The known mobility of Trp at the ?1 subsite and the influence of its environment, which is different in subset 1 and subset 2 family 10 enzymes, were taken into account in variant design. Q88A/R275A had the best ratio of p-nitrophenyl cellobioside vs p-nitrophenyl xylobioside hydrolyzing activity in the first series of variants. The crystal structure shows a movement of Trp274 compared to the native, as a result of loss of interaction with the long side chain of Arg275. The movement creates extra space for the hydroxymethyl of glucose, resulting in improved K_m on glucose derived substrates, while the negative effect on k_cat is compensated by the Q88A mutation, which also contributes to a further reduction of K_m. Further mutagenesis based on the Q88A/R275A variant resulted in 5.2 times improvement compared to the wild-type p-nitrophenyl cellobioside hydrolyzing activity, which is the best improvement obtained so far for an engineered xylanase.     

Crystal structures of decorated xylooligosaccharides bound to a family 10 xylanase from Streptomyces olivaceoviridis E-86

The family 10 xylanase from Streptomyces olivaceoviridis E-86 (SoXyn10A) consists of a GH10 catalytic domain, which is joined by a Gly/Pro-rich linker to a family 13 carbohydrate-binding module (CBM13) that interacts with xylan. To understand how GH10 xylanases and CBM13 recognize decorated xylans, the crystal structure of SoXyn10A was determined in complex with alpha-l-arabinofuranosyl- and 4-O-methyl-alpha-d-glucuronosyl-xylooligosaccharides. The bound sugars were observed in the subsites of the catalytic cleft and also in subdomains alpha and gamma of CBM13. The data reveal that the binding mode of the oligosaccharides in the active site of the catalytic domain is entirely consistent with the substrate specificity and, in conjunction with the accompanying paper, demonstrate that the accommodation of the side chains in decorated xylans is conserved in GH10 xylanases of SoXyn10A against arabinoglucuronoxylan. CBM13 was shown to bind xylose or xylooligosaccharides reversibly by using nonsymmetric sugars as the ligands. The independent multiple sites in CBM13 may increase the probability of substrate binding.     

Substrate specificity in glycoside hydrolase family 10. Structural and kinetic analysis of the Streptomyces lividans xylanase 10A

Endoxylanases are a group of enzymes that hydrolyze the beta-1, 4-linked xylose backbone of xylans. They are predominantly found in two discrete sequence families known as glycoside hydrolase families 10 and 11. The Streptomyces lividans xylanase Xyl10A is a family 10 enzyme, the native structure of which has previously been determined by x-ray crystallography at a 2.6 A resolution (Derewenda, U., Swenson, L., Green, R., Wei, Y., Morosoli, R., Shareck, F., Kluepfel, D., and Derewenda, Z. S. (1994) J. Biol. Chem. 269, 20811-20814). Here, we report the native structure of Xyl10A refined at a resolution of 1.2 A, which reveals many features such as the rare occurrence of a discretely disordered disulfide bond between residues Cys-168 and Cys-201. In order to investigate substrate binding and specificity in glycoside hydrolase family 10, the covalent xylobiosyl enzyme and the covalent cellobiosyl enzyme intermediates of Xyl10A were trapped through the use of appropriate 2-fluoroglycosides. The alpha-linked intermediate with the nucleophile, Glu-236, is in a (4)C(1) chair conformation as previously observed in the family 10 enzyme Cex from Cellulomonas fimi (Notenboom, V., Birsan, C., Warren, R. A. J., Withers, S. G., and Rose, D. R. (1998) Biochemistry 37, 4751-4758). The different interactions of Xyl10A with the xylobiosyl and cellobiosyl moieties, notably conformational changes in the -2 and -1 subsites, together with the observed kinetics on a range of aryl glycosides, shed new light on substrate specificity in glycoside hydrolase family 10.     

Crystal structures of the family 9 carbohydrate-binding module from Thermotoga maritima xylanase 10A in native and ligand-bound forms

The C-terminal module of the thermostable Thermotoga maritima xylanase 10A (CBM9-2) is a family 9 carbohydrate-binding module that binds to amorphous and crystalline cellulose and a range of soluble di- and monosaccharides as well as to cello and xylo oligomers of different degrees of polymerization [Boraston, A. B., Creagh, A. L., Alam, Md. M., Kormos, J. M., Tomme, P., Haynes, C. A., Warren, R. A. J., and Kilburn, D. G. (2001) Biochemistry 40, 6240-6247]. The crystal structure of CBM9-2 has been determined by the multiwavelength anomalous dispersion method to 1.9 A resolution. CBM9-2 assumes a beta-sandwich fold and contains three metal binding sites. The bound metal atoms, which are most likely calcium cations, are in an octahedral coordination. The crystal structures of CBM9-2 in complex with glucose and cellobiose were also determined in order to identify the sugar-binding site and provide insight into the structural basis for sugar binding by CBM9-2. The sugar-binding site is a solvent-exposed slot sufficient in depth, width, and length to accommodate a disaccharide. Two tryptophan residues are stacked together on the surface of the protein forming the sugar-binding site. From the complex structures with glucose and cellobiose, it was inferred that CBM9-2 binds exclusively to the reducing end of mono-, di-, and oligosaccharides with an intricate hydrogen-bonding network involving mainly charged residues, as well as stacking interactions by Trp175 and Trp71. The binding interactions are limited to disaccharides as was expected from calorimetric data. Comparison of the glucose and cellobiose complexes revealed surprising differences in binding of these two substrates by CBM9-2. Cellobiose was found to bind in a distinct orientation from glucose, while still maintaining optimal stacking and electrostatic interactions with the reducing end sugar.     

Novel sugar-binding specificity of the type XIII xylan-binding domain of a family F/10 xylanase from Streptomyces olivaceoviridis E-86

The type XIII xylan-binding domain (XBD) of a family F/10 xylanase (FXYN) from Streptomyces olivaceoviridis E-86 was found to be structurally similar to the ricin B chain which recognizes the non-reducing end of galactose and specifically binds to galactose containing sugars. The crystal structure of XBD [Fujimoto, Z. et al. (2000) J. Mol. Biol. 300, 575-585] indicated that the whole structure of XBD is very similar to the ricin B chain and the amino acids which form the galactose-binding sites are highly conserved between the XBD and the ricin B chain. However, our investigation of the binding abilities of wt FXYN and its truncated mutants towards xylan demonstrated that the XBD bound xylose-based polysaccharides. Moreover, it was found that the sugar-binding unit of the XBD was a trimer, which was demonstrated in a releasing assay using sugar ranging in size from xylose to xyloheptaose. These results indicated that the binding specificity of the XBD was different from those of the same family lectins such as the ricin B chain. Somewhat surprisingly, it was found that lactose could release the XBD from insoluble xylan to a level half of that observed for xylobiose, indicating that the XBD also possessed the same galactose recognition site as the ricin B chain. It appears that the sugar-binding pocket of the XBD has evolved from the ancient ricin super family lectins to bind additional sugar targets, resulting in the differences observed in the sugar-binding specificities between the lectin group (containing the ricin B chain) and the enzyme group.     

Rational design of peptide affinity ligands for the purification of therapeutic enzymes

Non‐mAb biologics represent a growing class of therapeutics under clinical development. Although affinity chromatography is a potentially attractive approach for purification, the development of platform technologies, such as Protein A for mAbs, has been challenging due to the inherent chemical and structural diversity of these molecules. Here, we present our studies on the rapid development of peptide affinity ligands for the purification of biologics using a prototypical enzyme therapeutic in clinical use. Employing a suite of de novo rational and combinatorial design strategies we designed and screened a library of peptides on microarray platforms for their ability to bind to the target with high affinity and selectivity in cell culture fluid. Lead peptides were evaluated on resin in batch conditions and compared with a commercially available resin to evaluate their efficacy. Two lead candidates identified from microarray studies provided high binding capacity to the target while demonstrating high selectivity against culture contaminants and product variants compared to a commercial resin system. These findings provide a proof‐of‐concept for developing affinity peptide‐based bioseparations processes for a target biologic. Peptide affinity ligand design and screening approaches presented in this work can also be easily translated to other biologics of interest. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:987–998, 2018     

Large-scale purification of xylanase T-6

Bacillus stearothermophilus T-6 produces an extracellular thermostable xylanase that can bleach paper pulp optimally at 60°C and pH 9.0. We developed an efficient method for purifying the enzyme from the cell broth by using successive steps of batch adsorption on the cellulosic cation exchanger SE-52. The optimal pH values for adsorption and elution are 5.5 and 9 respectively. The conductivity of the cell broth should remain below 7 mS/cm² and the suitable temperature range for adsorption is 15–60°C. The adsorption parameters are: maximum capacity, 118 mg enzyme/g adsorbent; dissociation constant, 0.6 mg/ml; partition coefficient 0.988. On the basis of these results, a large-scale (12 000 l) purification process was carried out resulting in a 55% final yield and over 95% pure enzyme.     

Module-intron correlation and intron sliding in family F/10 xylanase genes

Xylanases are classified into two families, numbered F/10 and G/11 according to the similarity of amino acid sequences of their catalytic domain (Henrissat, B., Bairoch, A., 1993. New families in the classification of glycosyl hydrolases based on amino acid sequence similarities. Biochem. J. 293, 781-788). Three-dimensional structure of the catalytic domain of the family F/10 xylanase was reported (White, A., Withers, S.G., Gilkes, N.R., Rose, D.R., 1994. Crystal structure of the catalytic domain of the beta-1,4-glycanase Cex from Cellulomonas fimi. Biochemistry 33, 12546-12552). The domain was decomposed into 22 modules by centripetal profiles (Go, M., Nosaka, M., 1987. Protein architecture and the origin of introns. Cold Spring Harbor Symp. Quant. Biol. 52, 915-924; Noguti, T., Sakakibara, H., Go, M., 1993. Localization of hydrogen-bonds within modules in barnase. Proteins 16, 357-363). A module is a contiguous polypeptide segment of amino acid residues having a compact conformation within a globular domain. Collected 31 intron sites of the family F/10 xylanase genes from fungus were found to be correlated to module boundaries with considerable statistical force (p values <0.001). The relationship between the intron locations and protein structures provides supporting evidence for the ancient origin of introns, because such a relationship cannot be expected by random insertion of introns into eukaryotic genes, but it rather suggests pre-existence of introns in the ancestral genes of prokaryotes and eukaryotes. A phylogenetic tree of the fungal and bacterial xylanase sequences made two clusters; one includes both the bacterial and fungal genes, but the other consists of only fungal genes. The mixed cluster of bacterial genes without introns and the fungal genes with introns further supports the ancient origin of introns. Comparison of the conserved base sequences of introns indicates that sliding of a splice site occurred in Aspergillus kawachii gene by one base from the ancestral position. Substrate-binding sites of xylanase are localized on eight modules, and introns are found at both termini of six out of these functional modules. This result suggests that introns might play a functional role in shuffling the exons encoding the substrate-binding modules.     

Cloning of the xylanase gene of Streptomyces lividans

The xylanase (xln) gene of Streptomyces lividans 1326 was cloned by functional complementation of the xylanase-negative and beta-1,4-glucan-glucanohydrolase-negative double mutant of S. lividans using the multicopy plasmid pIJ702. Three clones had a common 2-kb DNA fragment as determined by restriction mapping and Southern hybridization. These clones secreted a xylanase of Mr 43,000 which reacted with specific anti-xylanase antibodies and corresponded exactly to the enzyme previously isolated from the wild-type strain. The DNA fragment likely carried the full structural gene, the xln promoter and also the regulatory sequence, since the xylanase activity was inducible by xylan. Enzyme levels of up to 380 IU/ml of culture filtrate were obtained.     

Rapid purification of native SecA fromEscherichia coli: Development of a new affinity chromatography procedure

The SecA protein occupies a pivotal position in the public protein export pathway inEscherichia coli. The multifunctional SecA protein recognizes cytoplasmic factors associated with export including the presecretory protein and targets the complex to the inner membrane, where it acts in the early stages of protein translocation. The ability of SecA to bind ATP was the basis for the development of a novel, rapid purification scheme involving a single chromatographic step. Affinity chromatography was carried out on Red Sepharose CL-6B. The SecA present in crude extracts ofE. coli binds strongly to this dye-ligand matrix, and active protein was purified to greater than 90% homogeneity. The protein isolated by this procedure retained the previously described ATPase and RNA-binding activities of SecA. This approach should permit the rapid purification of SecA homologs from a variety microorganisms.     

The ARiBo tag: a reliable tool for affinity purification of RNAs under native conditions

Although RNA-based biological processes and therapeutics have gained increasing interest, purification of in vitro transcribed RNA generally relies on gel-based methods that are time-consuming, tedious and denature the RNA. Here, we present a reliable procedure for affinity batch purification of RNA, which exploits the high-affinity interaction between the boxB RNA and the N-peptide from bacteriophage λ. The RNA of interest is synthesized with an ARiBo tag, which consists of an activatable ribozyme (the glmS ribozyme) and the λBoxB RNA. This ARiBo-fusion RNA is initially captured on Glutathione-Sepharose resin via a GST/λN-fusion protein, and the RNA of interest is subsequently eluted by ribozyme self-cleavage using glucosamine-6-phosphate. Several GST/λN-fusion proteins and ARiBo tags were tested to optimize RNA yield and purity. The optimized procedure enables one to quickly obtain (3 h) highly pure RNA (>99%) under native conditions and with yields comparable to standard denaturing gel-based protocols. It is widely applicable to a variety of RNAs, including riboswitches, ribozymes and microRNAs. In addition, it can be easily adapted to a wide range of applications that require RNA purification and/or immobilization, including isolation of RNA-associated complexes from living cells and high-throughput applications.     

Cellulose affinity purification of fusion proteins tagged with fungal family 1 cellulose-binding domain

N- or C-terminal fusions of red-fluorescent protein (RFP) with various fungal cellulose-binding domains (CBDs) belonging to carbohydrate binding module (CBM) family 1 were expressed in a Pichia pastoris expression system, and the resulting fusion proteins were used to examine the feasibility of large-scale affinity purification of CBD-tagged proteins on cellulose columns. We found that RFP fused with CBD from Trichoderma reesei CBHI (CBD(Tr)(CBHI)) was expressed at up to 1.2g/l in the culture filtrate, which could be directly injected into the cellulose column. The fusion protein was tightly adsorbed on the cellulose column in the presence of a sufficient amount of ammonium sulfate and was efficiently eluted with pure water. Bovine serum albumin (BSA) was not captured under these conditions, whereas both BSA and the fusion protein were adsorbed on a phenyl column, indicating that the cellulose column can be used for the purification of not only hydrophilic proteins but also for hydrophobic proteins. Recovery of various fusion proteins exceeded 80%. Our results indicate that protein purification by expression of a target protein as a fusion with a fungal family 1 CBD tag in a yeast expression system, followed by affinity purification on a cellulose column, is simple, effective and easily scalable.     

Characterization of cellulase and xylanase activities of Streptomyces lividans

Summary The production of cellulases and of xylanase by Streptomyces lividans 1326 was studied under different growth conditions. The strain grew between 18°C and 46°C and is therefore thermotolerant. Submerged cultures of the microorganism, when grown on a defined salt medium containing xylan as main carbon source, exhibited an overall cellulolytic activity as determined by the filter paper test. S. lividans produced optimal levels of extracellular -1,4-glucan-glucanohydrolase (1 IU/ml) and large amounts of -1,4-xylanxylanohydrolase (50 IU/ml) at 40°C. A better production of both enzymes was observed when xylan instead of cellulose was used as substrate.The stability of the enzyme was found to be significantly greater than those of the cellulases and xylanases produced by other streptomycetes. The optimal incubation temperatures for the enzyme assays were 55°C and 60°C for CM-cellulase and xylanase respectively and optimal pH values were found in the range of pH 6–7.     

A novel tandem affinity purification strategy for the efficient isolation and characterisation of native protein complexes

Isolation and dissection of native multiprotein complexes is a central theme in functional genomics. The development of the tandem affinity purification (TAP) tag has enabled an efficient and large-scale purification of native protein complexes. However, the TAP tag features a size of 21 kDa and requires time consuming cleavage. By combining a tandem Strep-tag II with a FLAG-tag we were able to reduce the size of the TAP (SF-TAP) tag to 4.6 kDa. Both moieties have a medium affinity and avidity to their immobilised binding partners. This allows the elution of SF-tagged proteins under native conditions using desthiobiotin in the first step and the FLAG octapeptide in the second step. The SF-TAP protocol represents an efficient, fast and straightforward purification of protein complexes from mammalian cells within 2.5 h. The power of this novel method is demonstrated by the purification of Raf associated protein complexes from HEK293 cells and subsequent analysis of their protein interaction network by dissection of interaction patterns from the Raf binding partners MEK1 and 14-3-3.     

Overproduction, purification, and biochemical characterization of a xylanase (Xys1) from Streptomyces halstedii JM8.

Streptomyces halstedii JM8, isolated from straw, produces and secretes into the culture supernatant at least two proteins with hydrolytic activity towards xylan. The cloning of a DNA fragment of this microorganism in several Streptomyces strains permitted us to overproduce both proteins. N-terminal sequence analyses, immunoblot assays, and time course overproduction experiments allowed us to ensure that both xylanases were encoded by the same gene and that the smallest form (35 kDa) originated from the large one (45 kDa) by proteolytic cleavage on the C terminus. The production of both forms was studied in different strains carrying the gene in a multicopy plasmid. The best production was obtained with Streptomyces parvulus transformed with the plasmid pJM9, a pIJ702 derivative, which yielded 144 U/ml. Both forms of the xylanase were purified with a fast-performance liquid chromatography system and characterized biochemically. The optimal pH and temperature, for both, were 6.3 and 60 degrees C, respectively, in 7.5-min assays. Both proteins were highly stable in a wide range of pHs (4 to 10) and temperatures (4 to 50 degrees C); nevertheless, after 1-h incubations, both enzymes lost most of their activity at temperatures over 55 to 60 degrees C. Endoxylanolytic activity was demonstrated in both enzymes, but no beta-xylosidase activity was detected.     

High activity xylanase production by Streptomyces olivaceoviridis E-86

The effects of different factors on xylanase production by Streptomyces olivaceoviridis E-86 were studied under shake flask conditions. The best initial pH value of growth medium for xylanase production was pH 6.0. Corn cob xylan and beef peptone were the best C source and N source, respectively. The enzyme activity was doubled by addition of 1.5% (v/v) Tween-80 in the medium. By the combination of the above variables, the highest xylanase activity obtained was 1653 U/ml which is the highest ever reported from Streptomyces sp.     

Purification and characterization of a new xylanase (xylanase C) produced by Streptomyces lividans 66

Summary A third extracellular xylanase produced by Streptomyces lividans 66 was isolated from a clone obtained by shotgun cloning through functional complementation of a xylanase- and cellulase-negative mutant using the multicopy vector pIJ702. This enzyme, designated xylanase C, has a relative molecular mass of 22000 and acts on xylan similarly to xylanase B as an endo-type xylanase producing short-chain oligoxylosides. Its specific activity determined at 1100 IU·mg^–1 of protein corresponds on a molecular basis to that of xylanase B and is about three times that of xylanase A. The enzyme shows optimal activity at pH 6.0 and 57°C, values that correspond closely to those observed previously for xylanase A and B. Xylanase C appears not to be glycosylated and has a pI > 10.25. Its K _m and V _max on birchwood xylan are 4.1 mg·ml^–1 and 3.0 mol·min^–1·mg^–1 of enzyme respectively. Whereas specific antibodies raised against xylanase A show no cross-reaction with either xylanase B or with xylanase C, the anti-(xylanase C) antibodies react slightly with xylanase B but not with xylanase A. A comparison of hydrolysis products obtained by reacting individually the three enzymes with birchwood xylan showed characteristic endo-activity patterns for xylanases B and C, whereas xylanase A hydrolysed the substrate preferentially into xylobiose and xylotriose. Sequential xylanase action on the same substrates showed synergistic hydrolysis only when endo-xylanase activity was followed by that of xylanase A.     

Thermostable xylanase from Streptomyces thermocyaneoviolaceus for optimal production of xylooligosaccharides

A thermo stable xylanase was purified from Streptomyces thermocyaneoviolaceus M049 for the production of xylooligosaccharides from xylan. The enzyme showed thermostability by maintaining 65% of remaining enzyme activity after 1 h heat treatment at 70°C. The molecular weight of the purified protein was 35 kDa in SDS-PAGE, and the optimal pH and temperature for the enzymatic activity were pH 5.0 and 60°C, respectively. N-terminal amino acid sequences of the purified xylanase, DTITSNQTGTHNGYF, were similar to StxII from S. Thermoviolaceus and XlnB from S. lividans. Using those two genes, stxll and xlnB as probe DNA, a gene encoding xylanase, xynB, was cloned from genomic library of S. thermocyaneoviolaceus M049. The open reading frame of the xynB was composed of 1008 nucleotide sequences. Compared to N-terminal sequences from purified enzyme, it was proposed that the XynB contained a 40 amino acid long signal peptide to the N-terminus. For easy production and purification, a XynB overproduction strain was constructed using pET21a(+) and strain E. coli BLR(DE3). Consequently, the recombinant enzyme was tested for the production of xylooligosaccharides through TLC and HPLC analyses.