Expression inEscherichia coliof Y5-Mutant and N-terminal Domain-Deleted DNA Gyrase B Proteins Affects Strongly Plasmid Maintenance

Escherichia coliDNA gyrase B subunit (GyrB) is composed of a 43-kDa N-terminal domain containing an ATP-binding site and a 47-kDa C-terminal domain involved in the interaction with the gyrase A subunit (GyrA). Site-directed mutagenesis was used to substitute, in both the entire GyrB subunit and its 43-kDa N-terminal fragment, the amino acid Y5 by either a serine (Y5S) or a phenylalanine residue (Y5F). Under standard conditions, cells bearing Y5S or Y5F mutant GyrB expression plasmids produced significantly less recombinant proteins than cells transformed with the wild-type plasmid. This dramatic decrease in expression of mutant GyrB proteins was not observed when the corresponding N-terminal 43-kDa mutant plasmids were used. Examination of the plasmid content of the transformed cells after induction showed that the Y5F and Y5S GyrB protein level was correlated with the plasmid copy number. By repressing tightly the promoter activity encoded by these expression vectors during cell growth, it was possible to restore the normal level of the mutant GyrB encoding plasmids in the transformed bacteria. Treatment with chloramphenicol before protein induction enabled large overexpression of the GyrB mutant Y5F and Y5S proteins. In addition, the decrease in plasmid copy number was also observed when the 47-kDa C-terminal fragment of the GyrB subunit was expressed in bacteria grown under standard culture conditions. Analysis of DNA supercoiling and relaxation activities in the presence of GyrA demonstrated that purified Y5-mutant GyrB proteins were deficient for ATP-dependent gyrase activities. Taken together, these results show that Y5F and Y5S mutant GyrB proteins, but not the corresponding 43-kDa N-terminal fragments, competein vivowith the bacterial endogenous GyrB subunit of DNA gyrase, thereby reducing the plasmid copy number in the transformed bacteria by probably acting on the level of negative DNA supercoilingin vivo.This competition could be mediated by the presence of the intact 47-kDa C-terminal domain in the Y5F and Y5S mutant GyrB subunits. This study demonstrates also that the amino acid Y5 is a crucial residue for the expression of the gyrase B activityin vivo.Thus, ourin vivoapproach may also be useful for detecting other important amino acids for DNA gyrase activity, as mutations affecting the ATPase activity or the GyrB/GyrB or GyrB/GyrA protein interactions.     

Improved solubility of TEV protease by directed evolution

The efficiency and high specificity of tobacco etch virus (TEV) protease has made it widely used for cleavage of recombinant fusion proteins. However, the production of TEV protease in E. coli is hampered by low solubility. We have subjected the gene encoding TEV protease to directed evolution to improve the yield of soluble protein. Libraries of mutated genes obtained by error-prone PCR and gene shuffling were introduced into the Gateway cloning system for facilitated transfer between vectors for screening, purification, or other applications. Fluorescence based in vivo solubility screening was carried out by cloning the libraries into a plasmid encoding a C-terminal GFP fusion. Mutant genes giving rise to high GFP fluorescence intensity indicating high levels of soluble TEV-GFP were subsequently transferred to a vector providing a C-terminal histidine tag for expression, purification, and activity tests of mutated TEV. We identified a mutant, TEV(SH), in which three amino acid substitutions result in a five-fold increase in the yield of purified protease with retained activity.     

Mechanisms for defining supercoiling set point of DNA gyrase orthologs: I. A nonconserved acidic C-terminal tail modulates Escherichia coli gyrase activity

DNA topoisomerases manage chromosome supercoiling and organization in all cells. Gyrase, a prokaryotic type IIA topoisomerase, consumes ATP to introduce negative supercoils through a strand passage mechanism. All type IIA topoisomerases employ a similar set of catalytic domains for function; however, the activity and specificity of gyrase are augmented by a specialized DNA binding and wrapping element, termed the C-terminal domain (CTD), which is appended to its GyrA subunit. We have discovered that a nonconserved, acidic tail at the extreme C terminus of the Escherichia coli GyrA CTD has a dramatic and unexpected impact on gyrase function. Removal of the CTD tail enables GyrA to introduce writhe into DNA in the absence of GyrB, an activity exhibited by other GyrA orthologs, but not by wild-type E. coli GyrA. Strikingly, a "tail-less" gyrase holoenzyme is markedly impaired for DNA supercoiling capacity, but displays normal ATPase function. Our findings reveal that the E. coli GyrA tail regulates DNA wrapping by the CTD to increase the coupling efficiency between ATP turnover and supercoiling, demonstrating that CTD functions can be fine-tuned to control gyrase activity in a highly sophisticated manner.     

Facilitation of expression and purification of an antimicrobial peptide by fusion with baculoviral polyhedrin in Escherichia coli

Several fusion strategies have been developed for the expression and purification of small antimicrobial peptides (AMPs) in recombinant bacterial expression systems. However, some of these efforts have been limited by product toxicity to host cells, product proteolysis, low expression levels, poor recovery yields, and sometimes an absence of posttranslational modifications required for biological activity. For the present work, we investigated the use of the baculoviral polyhedrin (Polh) protein as a novel fusion partner for the production of a model AMP (halocidin 18-amino-acid subunit; Hal18) in Escherichia coli. The useful solubility properties of Polh as a fusion partner facilitated the expression of the Polh-Hal18 fusion protein ( approximately 33.6 kDa) by forming insoluble inclusion bodies in E. coli which could easily be purified by inclusion body isolation and affinity purification using the fused hexahistidine tag. The recombinant Hal18 AMP ( approximately 2 kDa) could then be cleaved with hydroxylamine from the fusion protein and easily recovered by simple dialysis and centrifugation. This was facilitated by the fact that Polh was soluble during the alkaline cleavage reaction but became insoluble during dialysis at a neutral pH. Reverse-phase high-performance liquid chromatography was used to further purify the separated recombinant Hal18, giving a final yield of 30% with >90% purity. Importantly, recombinant and synthetic Hal18 peptides showed nearly identical antimicrobial activities against E. coli and Staphylococcus aureus, which were used as representative gram-negative and gram-positive bacteria, respectively. These results demonstrate that baculoviral Polh can provide an efficient and facile platform for the production or functional study of target AMPs.     

Staphylococcus aureus gyrase-quinolone-DNA ternary complexes fail to arrest replication fork progression in vitro. Effects of salt on the DNA binding mode and the catalytic activity of S. aureus gyrase

Type II topoisomerases bind to DNA at the catalytic domain across the DNA gate. DNA gyrases also bind to DNA at the non-homologous C-terminal domain of the GyrA subunit, which causes the wrapping of DNA about itself. This unique mode of DNA binding allows gyrases to introduce the negative supercoils into DNA molecules. We have investigated the biochemical characteristics of Staphylococcus aureus (S. aureus) gyrase. S. aureus gyrase is known to require high concentrations of potassium glutamate (K-Glu) for its supercoiling activity. However, high concentrations of K-Glu are not required for its relaxation and decatenation activities. This is due to the requirement of high concentrations of K-Glu for S. aureus gyrase-mediated wrapping of DNA. These results suggest that S. aureus gyrase can bind to DNA at the catalytic domain independent of K-Glu concentration, but high concentrations of K-Glu are required for the binding of the C-terminal domain of GyrA to DNA and the wrapping of DNA. Thus, salt modulates the DNA binding mode and the catalytic activity of S. aureus gyrase. Quinolone drugs can stimulate the formation of covalent S. aureus gyrase-DNA complexes, but high concentrations of K-Glu inhibit the formation of S. aureus gyrase-quinolone-DNA ternary complexes. In the absence of K-Glu, ternary complexes formed with S. aureus gyrase cannot arrest replication fork progression in vitro, demonstrating that the formation of a wrapped ternary complex is required for replication fork arrest by a S. aureus gyrase-quinolone-DNA ternary complex.     

The structure of the transition state of the heterodimeric topoisomerase I of Leishmania donovani as a vanadate complex with nicked DNA

Type IB topoisomerases are essential enzymes that are responsible for relaxing superhelical tension in DNA by forming a transient covalent nick in one strand of the DNA duplex. Topoisomerase I is a target for anti-cancer drugs such as camptothecin, and these drugs also target the topoisomerases I in pathogenic trypanosomes including Leishmania species and Trypanosoma brucei. Most eukaryotic enzymes, including human topoisomerase I, are monomeric. However, for Leishmania donovani, the DNA-binding activity and the majority of residues involved in catalysis are located in a large subunit, designated TOP1L, whereas the catalytic tyrosine residue responsible for covalent attachment to DNA is located in a smaller subunit, called TOP1S. Here, we present the 2.27A crystal structure of an active truncated L.donovani TOP1L/TOP1S heterodimer bound to nicked double-stranded DNA captured as a vanadate complex. The vanadate forms covalent linkages between the catalytic tyrosine residue of the small subunit and the nicked ends of the scissile DNA strand, mimicking the previously unseen transition state of the topoisomerase I catalytic cycle. This structure fills a critical gap in the existing ensemble of topoisomerase I structures and provides crucial insights into the catalytic mechanism.     

Generation of recombinant cytoplasmic domain of epidermal growth factor receptor with intrinsic protein tyrosine kinase activity

We have generated a recombinant baculovirus using the high expression vector pVL941 containing the complementary DNA encoding the intracellular domain of the human epidermal growth factor receptor (EGFR-IC). Upon infection of Spodoptera frugiperda insect cells, protein tyrosine kinase-active EGFR-IC was produced. The expressed protein has a molecular weight of 61,000 and is specifically recognized by antibodies directed against peptides representing different regions of human EGFR-IC. Upon sonication of infected cells, EGFR-IC was detected in both the soluble and insoluble fractions of the cell lysate. About 20-50% of the expressed EGFR-IC was soluble. Metabolic labeling and protein analyses showed that EGFR-IC comprised 7% of newly synthesized proteins in the cytoplasmic lysate and 0.1-0.2% of the total soluble protein. We have used a three-step purification procedure (fast-Q-Sepharose and phenyl-Sepharose column chromatographies and 30% ammonium sulfate precipitation) to purify EGFR-IC to 85% purity with 15-20% recovery from the initial soluble lysate. A yield of 3-4 mg of purified EGFR-IC has been consistently produced from 20 roller bottles with 2-4 x 10(8) infected cells/bottle. The tyrosine kinase activity was retained through purification. The enzyme demonstrated much higher autophosphorylation activity in the presence of Mn2+ than Mg2+. Phosphopeptide mapping revealed the same autophosphorylation sites utilized by EGFR-IC as those identified in wild-type EGFR. EGFR-IC-catalyzed phosphorylation of either a synthetic peptide representing the major autophosphorylation site or angiotensin II showed that the baculovirus-expressed EGFR-IC exhibits similar enzymatic kinetic characteristics to the intact activated EGFR kinase.     

A strategy for the expression of recombinant proteins traditionally hard to purify

We have developed a series of plasmid vectors for the soluble expression and subsequent purification of recombinant proteins that have historically proven to be extremely difficult to purify from Escherichia coli. Instead of dramatically overproducing the target protein, it is expressed at a low basal level that facilitates the correct folding of the recombinant protein and increases its solubility. Highly active recombinant proteins that are traditionally difficult to purify are readily purified using standard affinity tags and conventional chromatography. To demonstrate the utility of these vectors, we have expressed and purified full-length human DNA polymerases η, ι, and ν from E. coli and show that the purified DNA polymerases are catalytically active in vitro.     

A novel multi-affinity tag system to produce high levels of soluble and biotinylated proteins in Escherichia coli

We describe here a novel multi-affinity tag vector that can be used to produce high levels of soluble, in vivo biotinylated proteins in Escherichia coli. This system combines the solubility-enhancing ability of maltose-binding protein (MBP), the versatility of the hexahistidine tag (His(6)), and the site-specific in vivo biotinylation of a 15-amino acid tag (AviTag). We used this multi-tag system in an attempt to improve expression levels of two prokaryotic proteins-elongation factor Tu (TufB) and DNA gyrase subunit A (GyrA)-as well as two eukaryotic nuclear receptors-glucocorticoid receptor (GR) and small heterodimer partner (SHP). The multi-tag system not only vastly improved the expression of the two prokaryotic proteins tested, but also yielded complete, site-specific, in vivo biotinylation of these proteins. The results obtained from the TufB expression and purification are presented and discussed in detail. The nuclear receptors, though soluble as fusion partners, failed to remain soluble once the MBP tag was cleaved. Despite this limitation of the system, the multi-affinity tag approach is a useful system that can improve expression of some otherwise insoluble or poorly expressing proteins, to obtain homogeneous, purified, fully biotinylated protein for downstream applications.     

重组蛋白ES-Kringle5的表达、纯化及活性检测

目的：利用基因工程方法原核表达重组融合蛋白ES-Kringle5并进行纯化及活性检测。方法：ES-Kringle5是将内皮抑素N端的前27个氨基酸与Kringle5通过连接肽相连的重组融合蛋白,合成该重组蛋白的基因片段并插入载体pMD18-T中,然后克隆至大肠杆菌表达载体pET25b中并转化E.coli BL21（DE3）。乳糖诱导表达后经Ni-NTA亲和层析纯化后获得目的蛋白。通过抑制HUVEC细胞增殖实验检测其生物学活性。结果：重组质粒构建正确。利用乳糖诱导表达并降低诱导温度能增加目的蛋白的产量及可溶性表达。纯化后的重组蛋白纯度大于95%。生物学活性证明该重组蛋白具有抑制HUVEC的增殖能力。结论：具有生物学活性的重组蛋白ES-Kringle5可在大肠杆菌中高效表达,为研究其体内药效、药代及安全性评价奠定了基础。     

Molecular cloning of the DNA gyrase genes from Methylovorus sp. strain SS1 and the mechanism of intrinsic quinolone resistance in methylotrophic bacteria

The genes encoding the DNA gyrase A (GyrA) and B subunits (GyrB) of Methylovorus sp. strain SS1 were cloned and sequenced. gyrA and gyrB coded for proteins of 846 and 799 amino acids with calculated molecular weights of 94,328 and 88,714, respectively, and complemented Escherichia coli gyrA and gyrB temperature sensitive (ts) mutants. To analyze the role of type II topoisomerases in the intrinsic quinolone resistance of methylotrophic bacteria, the sequences of the quinolone resistance-determining regions (QRDRs) in the A subunit of DNA gyrase and the C subunit (ParC) of topoisomerase IV (Topo IV) of Methylovorus sp. strain SS1, Methylobacterium extorquens AM1 NCIB 9133, Methylobacillus sp, strain SK1 DSM 8269, and Methylophilus methylotrophus NCIB 10515 were determined. The deduced amino acid sequences of the QRDRs of the ParCs in the four methylotrophic bacteria were identical to that of E. coli ParC. The sequences of the QRDR in GyrA were also identical to those in E. coli GyrA except for the amino acids at positions 83, 87, or 95. The Ser83 to Thr substitution in Methylovorus sp. strain SS1, and the Ser83 to Leu and Asp87 to Asn substitutions in the three other methylotrophs, agreed well with the minimal inhibitory concentrations of quinolones in the four bacteria, suggesting that these residues play a role in the intrinsic susceptibility of methylotrophic bacteria to quinolones.     

Functional expression of the lipase gene Lip2 of <Emphasis Type="Italic">Pleurotus</Emphasis> <Emphasis Type="Italic">sapidus</Emphasis> in <Emphasis Type="Italic">Escherichia</Emphasis> <Emphasis Type="Italic">coli</Emphasis>

The lipase Lip2 of the edible basidiomycete, Pleurotus sapidus, is an extracellular enzyme capable of hydrolysing xanthophyll esters with high efficiency. The gene encoding Lip2 was expressed in Escherichia coli TOP10 using the gene III signal sequence to accumulate proteins in the periplasmatic space. The heterologous expression under control of the araBAD promoter led to the high level production of recombinant protein, mainly as inclusion bodies, but partially in a soluble and active form. A fusion with a C-terminal His tag was used for purification and immunochemical detection of the target protein. This is the first example of a heterologous expression and periplasmatic accumulation of a catalytically active lipase from a basidiomycete fungus.     

A freeze-thaw method for disintegration of Escherichia coli cells producing T7 lysozyme used in pBAD expression systems

The pLysN plasmid containing the T7 lysozyme gene under control of the lac promoter was constructed to facilitate cell disintegration after expression of recombinant proteins in arabinose-induced expression systems. The usefulness of this plasmid was tested in Escherichia coli TOP10 and E. coli LMG194 cells carrying pBADMHADgeSSB plasmid containing Deinococcus geothermalis SSB protein gene under control of the araBAD promoter. The results showed that low-level expression of T7 lysozyme did not interfere with the target SSB protein production, and that the freezing-thawing treatment was sufficient for disruption of the E. coli cells producing low amounts of T7 lysozyme.     

霍乱毒素B亚单位基因（CtxB）的克隆及其表达

从霍乱弧菌中抽提基因组ＤＮＡ,用ＰＣＥＲ方法获取霍乱毒素Ｂ亚单位基因（ＣｔｘＢ）。序列分析结果表明,ＣｔｘＢ基因编码１２４个氨基酸,其中编码６２位Ｔｈｒ的密码子与文献报道有差异。将ＣｔｘＢ基因插入质粒ｐＧＥＸ－４Ｔ－２,构建ｐＧＥＸ－ＣＴＸＢ表达质粒,转化大肠相菌ＢＬ２１（ＤＥ３０,筛选表达菌株ＣＴＸＢ／ＢＬ２１。工程株经ＩＰＴＧ诱导表达,可产生大量的表达蛋白,经ＳＤＳ－ＰＡＧＥ分析,融合蛋白分子     

The "GyrA-box" is required for the ability of DNA gyrase to wrap DNA and catalyze the supercoiling reaction

DNA gyrase is the only topoisomerase that can introduce negative supercoils into DNA. It is thought that the binding of conventional type II topoisomerases, including topoisomerase IV, to DNA takes place at the catalytic domain across the DNA gate, whereas DNA gyrase binds to DNA not only at the amino-terminal catalytic domain but also at the carboxyl-terminal domain (CTD) of the GyrA subunit. The binding of the GyrA CTD to DNA allows gyrase to wrap DNA around itself and catalyze the supercoiling reaction. Recent structural studies, however, have revealed striking similarities between the GyrA CTD and the ParC CTD, as well as the ability of the ParC CTD to bind and bend DNA. Thus, the molecular basis of gyrase-mediated wrapping of DNA needs to be reexamined. Here, we have conducted a mutational analysis to determine the role of the "GyrA-box," a 7-amino acid-long motif unique to the GyrA CTD, in determining the DNA binding mode of gyrase. Either a deletion of the entire GyrA-box or substitution of the GyrA-box with 7 Ala residues abolishes the ability of gyrase to wrap DNA around itself and catalyze the supercoiling reaction. However, these mutations do not affect the relaxation and decatenation activities of gyrase. Thus, the presence of a GyrA-box allows gyrase to wrap DNA and catalyze the supercoiling reaction. The consequence of the loss of the GyrA-box during evolution of bacterial type II topoisomerases is discussed.     

弗氏志贺菌5a 型 M90T 株 ClpB 蛋白在大肠杆菌中的融合表达和纯化

目的：构建弗氏志贺菌cZp8基因的原核表达质粒,在大肠杆菌中表达后,纯化带T7标签的ClpB蛋白。方法与结果：PCR扩增得到线性化表达载体pET24a与2574bp的c加曰基因片段,利用不依赖连接反应的克隆法（LIC）进行克隆,得到重组质粒pET-ClpB,转入大肠杆菌BL21（DE3）中进行诱导表达,通过一系列条件优化,确定可溶性表达条件为在30℃下、用1mmol／LIPTG诱导2h;利用抗T7单克隆抗体琼脂糖珠进行亲和纯化,得到了纯度很高的相对分子质量为95×10^3的ClpB-T7融合蛋白。结论：实现了ClpB-T7在大肠杆菌中的可溶性表达,并纯化获得了高纯度的融合蛋白。     

Construction of a mini-intein fusion system to allow both direct monitoring of soluble protein expression and rapid purification of target proteins

Affinity purification of recombinant proteins has been facilitated by fusion to a modified protein splicing element (intein). The fusion protein expression can be further improved by fusion to a mini-intein, i.e. an intein that lacks an endonuclease domain. We synthesized three mini-inteins using overlapping oligonucleotides to incorporate Escherichia coli optimized codons and allow convenient insertion of an affinity tag between the intein (predicted) N- and C-terminal fragments. After examining the splicing and cleavage activities of the synthesized mini-inteins, we chose the mini-intein most efficient in thiol-induced N-terminal cleavage for constructing a novel intein fusion system. In this system, green fluorescent protein (GFP) was fused to the C-terminus of the affinity-tagged mini-intein whose N-terminus was fused to a target protein. The design of the system allowed easy monitoring of soluble fusion protein expression by following GFP fluorescence, and rapid purification of the target protein through the intein-mediated cleavage reaction. A total of 17 target proteins were tested in this intein-GFP fusion system. Our data demonstrated that the fluorescence of the induced cells could be used to measure soluble expression of the intein fusion proteins and efficient intein cleavage activity. The final yield of the target proteins exhibited a linear relationship with whole cell fluorescence. The intein-GFP system may provide a simple route for monitoring real time soluble protein expression, predicting final product yields, and screening the expression of a large number of recombinant proteins for rapid purification in high throughput applications.     

The structural basis for substrate specificity in DNA topoisomerase IV

Most bacteria possess two type IIA topoisomerases, DNA gyrase and topo IV, that together help manage chromosome integrity and topology. Gyrase primarily introduces negative supercoils into DNA, an activity mediated by the C-terminal domain of its DNA binding subunit (GyrA). Although closely related to gyrase, topo IV preferentially decatenates DNA and relaxes positive supercoils. Here we report the structure of the full-length Escherichia coli ParC dimer at 3.0 A resolution. The N-terminal DNA binding region of ParC is highly similar to that of GyrA, but the ParC dimer adopts a markedly different conformation. The C-terminal domain (CTD) of ParC is revealed to be a degenerate form of the homologous GyrA CTD, and is anchored to the top of the N-terminal domains in a configuration different from that thought to occur in gyrase. Biochemical assays show that the ParC CTD controls the substrate specificity of topo IV, likely by capturing DNA segments of certain crossover geometries. This work delineates strong mechanistic parallels between topo IV and gyrase, while explaining how structural differences between the two enzyme families have led to distinct activity profiles. These findings in turn explain how the structures and functions of bacterial type IIA topoisomerases have evolved to meet specific needs of different bacterial families for the control of chromosome superstructure.     

Enhanced purification of plasmid DNA using Q-Sepharose by modulation of alcohol concentrations

Ion-exchange chromatography is one of the most commonly used methods for plasmid preparation. In this study a modified method was used to purify plasmid from bacterial lysate using Q-Sepharose. Incorporation of alcohols into the washing buffers enhanced the separation of plasmid from RNA and proteins. The use of isopropanol and ethanol achieved a high yield and purity whereas the use of methanol failed to improve the plasmid purification using Q-Sepharose by batch adsorption-desorption. Stepwise elution containing various concentrations of isopropanol and NaCl was used in preparative chromatography to enhance the plasmid purification. The same stepwise elution was applied to the chromatography columns packed with 0.5, 20, and 200 ml of Q-Sepharose for plasmid purification from 7.5, 300, and 3000 ml bacterial broth, respectively. Complete separation of DNA from RNA and proteins was achieved under gravity flow by modulation of the alcohol concentrations in the stepwise elution. These three scales of chromatography maintained an approximate plasmid yield and the purified plasmid contained undetectable levels of RNA and protein.