Chemiresistive DNA hybridization sensor with electrospun nanofibers: A method to minimize inter-device variability.

Chemiresistive platforms are best suited for developing DNA hybridization detection systems, owing to their ease of fabrication, simple detection methodology and amenability towards electronics. In this work, we report development of a generic, robust, electrospun nanofiber based interdigitated chemiresistive platform for DNA hybridization detection. The platform comprises of interdigitated metal electrodes decorated with electrospun nanofibers on the top. Two approaches viz., drop casting of graphene doped Mn2O3 nanofibers (GMnO) and direct electrospinning of polyaniline/polyethylene oxide (PANi/PEO) composite nanofibers, have been utilized to decorate these electrodes. In both approaches, inter-device variability, a key challenge for converting this proof-of-concept into a tangible prototype/product, has been addressed using a shadow masking technique. Consequently, the relative standard deviation for multiple PANi/PEO nanofiber based chemiresistors has been brought down from 17.82% (without shadow masking) to 4.41% (with shadow masking). The nanofibers are further modified with single-stranded probe DNAs, to capture a desired hybridization event. To establish the generic nature of the platform, detection of multiple target DNAs has been successfully demonstrated. These targets include dengue virus specific consensus primer (DENVCP) and four DNAs corresponding to Staphylococcus aureus specific genes, namely nuc, mecA, vanA and protein A. The chemiresistive detection of DENVCP has been performed in the concentration range of 10 fM - 1 µM, whereas the detection of the other targets has been carried out in the range of 1 pM - 1 µM. Using a 3σ method, we have estimated the limit of detection for the chemiresistive detection of DENVCP to be 1.9 fM.

Mycoplasma agalactiae MAG_5040 is a Mg2+-dependent, sugar-nonspecific SNase recognised by the host humoral response during natural infection.

In this study the enzymatic activity of Mycoplasma agalactiae MAG_5040, a magnesium-dependent nuclease homologue to the staphylococcal SNase was characterized and its antigenicity during natural infections was established. A UGA corrected version of MAG_5040, lacking the region encoding the signal peptide, was expressed in Escherichia coli as a GST fusion protein. Recombinant GST-MAG_5040 exhibits nuclease activity similar to typical sugar-nonspecific endo- and exonucleases, with DNA as the preferred substrate and optimal activity in the presence of 20 mM MgCl2 at temperatures ranging from 37 to 45°C. According to in silico analyses, the position of the gene encoding MAG_5040 is consistently located upstream an ABC transporter, in most sequenced mycoplasmas belonging to the Mycoplasma hominis group. In M. agalactiae, MAG_5040 is transcribed in a polycistronic RNA together with the ABC transporter components and with MAG_5030, which is predicted to be a sugar solute binding protein by 3D modeling and homology search. In a natural model of sheep and goats infection, anti-MAG_5040 antibodies were detected up to 9 months post infection. Taking into account its enzymatic activity, MAG_5040 could play a key role in Mycoplasma agalactiae survival into the host, contributing to host pathogenicity. The identification of MAG_5040 opens new perspectives for the development of suitable tools for the control of contagious agalactia in small ruminants.

A rapid, high-throughput screening method for carriage of methicillin-resistant Staphylococcus aureus.

Rapid screening of methicillin-resistant Staphylococcus aureus (MRSA) colonization prior to hospital admittance is important to reduce nosocomial infections and health care costs. Molecular detection of mecA and S. aureus specific target genes has become widely established for this purpose. However, there are still limitations in potential for high-throughput screening in the methods described. We have compared the time aspects and workload of four different DNA preparation platforms, resulting in an automated and simple MRSA screening method which combines two liquid handling systems and a simple lysis buffer. We have further transferred our in-house dual real-time PCR to a fast-PCR protocol, reducing the time and labour spent on these samples to a minimum.

An ultra-high sensitive platform for fluorescence detection of micrococcal nuclease based on graphene oxide.

Micrococcal nuclease (MNase) is the extracellular nuclease of Staphylococcus aureus (S. aureus). It preferentially digests single-stranded nucleic acids. The existence of MNase can be the standard to identify S. aureus and the content of MNase can be used to evaluate the pathogenicity of S. aureus. Herein, an ultra-high sensitive and selective fluorescent sensing platform for MNase is developed based on MNase-induced DNA strand scission and the difference in affinity of graphene oxide (GO) for single-stranded DNA containing different numbers of bases in length. In the absence of MNase, the adsorption of the dye-labeled ssDNA on GO makes the dyes close proximity to GO surface resulting in high efficiency quenching of fluorescence of the dyes. Conversely, and very importantly, in the presence of MNase, it cleaves the dye-labeled ssDNA into small fragments. The introduction of GO into the sensing solution results in weak quenching of the fluorescence of the dyes due to the weak affinity of the short dye-labeled oligonuleotide fragment to GO, and the fluorescence intensity gradually increases with increasing concentration of MNase. MNase can be detected in a range of 8×10⁻5 to 1.6×10⁻³ unit/mL with a detection limit of 2.7×10⁻5 unit/mL and good selectivity. The detection limit is of two orders of magnitude lower than those reported fluorescence MNase assays. Moreover, when the GO-based biosensor is used in S. aureus sample assays, preeminent fluorescence signals are obtained, thus the platform of the GO-based biosensor can be used to detect MNase in real-world samples.

Production and purification of staphylococcal nuclease in Lactococcus lactis using a new expression-secretion system and a pH-regulated mini-reactor.

BACKGROUND: Staphylococcal (or micrococcal) nuclease or thermonuclease (SNase or Nuc) is a naturally-secreted nucleic acid degrading enzyme that participates in Staphylococcus aureus spread in the infected host. Purified Nuc protein can be used as an exogenous reagent to clear cellular extracts and improve protein purification. Here, a recombinant form of Nuc was produced and secreted in a Gram-positive host, Lactococcus lactis, and purified from the culture medium. RESULTS: The gene segment corresponding to the S. aureus nuclease without its signal peptide was cloned in an expression-secretion vector. It was then fused to a lactococcal sequence encoding a signal peptide, and expressed under the control of a lactococcal promoter that is inducible by zinc starvation. An L. lactis subsp cremoris model strain (MG1363) transformed with the resulting plasmid was grown in either of two media (GM17v and CDM) that are free of animal compounds, allowing GMP (Good Manufacturing Practice) production. Induction conditions (concentration of the metal chelator EDTA and timing of addition) in small-scale pH-regulated fermentors were optimized using LacMF (Lactis Multi-Fermentor), a home-made parallel fermentation control system able to monitor 12 reactors simultaneously. Large amounts of recombinant Nuc (rNuc) were produced and secreted in both media, and rNuc was purified from GM17v medium in a single-step procedure. CONCLUSIONS: In L. lactis, rNuc production and secretion were optimal after induction by 0.5 mM EDTA in small scale (200 mL) GM17v exponential phase cultures (at an OD(600) of 2), leading to a maximal protein yield of 210 mg per L of culture medium. Purified rNuc was highly active, displaying a specific activity of 2000 U/mg.

Recovery of nuclease produced by Lactococcus lactis using expanded bed ion exchange chromatography.

Expanded bed-ionic exchange chromatography (EB-IEC) was used for the recovery and purification of recombinant staphylococcal nuclease secreted by Lactococcus lactis. At the end of the fermentation process, the nuclease activity reached 39 U ml(-1). The EB-IEC performances were firstly evaluated with clarified culture broth. The isocratic elution with 0.5 M NaCl led to approximately 80% of nuclease recovery. Proceeding with 3-fold bed expansion resulted in a reduction of the resin capacity by a factor of 32% compared to the process in a packed bed configuration. Simplification of the early purification steps was reached by loading immediately the unclarified culture broth previously diluted to reduce conductivity. Presence of Cells did not affect the chromatography performances resulting in 55-fold purification with the same yield.

The effects of amino acid replacements of glycine 20 on conformational stability and catalysis of staphylococcal nuclease.

Staphylococcal nuclease (SNase) is a well-established model for protein folding studies. Its three-dimensional structure has been determined. The enzyme, Ca2+, and DNA or RNA substrate form a ternary complex. Glycine 20 is the second position of the first beta-turn of SNase, which may serve as the folding initiation site for the SNase polypeptide. To study the role of Gly20 in the conformational stability and catalysis of SNase, three mutants, in which Gly20 was replaced by alanine, valine, or isoleucine, were constructed and studied by using circular dichroism spectra, intrinsic and ANS-binding fluorescence spectra, stability and activity assays. The mutations have little effect on the conformational integrity of the mutants. However, the catalytic activity is reduced drastically by the mutations, and the stability of the protein is progressively decreased in the order G20A

A micrococcal nuclease homologue in RNAi effector complexes.

RNA interference (RNAi) regulates gene expression by the cleavage of messenger RNA, by mRNA degradation and by preventing protein synthesis. These effects are mediated by a ribonucleoprotein complex known as RISC (RNA-induced silencing complex). We have previously identified four Drosophila components (short interfering RNAs, Argonaute 2 (ref. 2), VIG and FXR) of a RISC enzyme that degrades specific mRNAs in response to a double-stranded-RNA trigger. Here we show that Tudor-SN (tudor staphylococcal nuclease)--a protein containing five staphylococcal/micrococcal nuclease domains and a tudor domain--is a component of the RISC enzyme in Caenorhabditis elegans, Drosophila and mammals. Although Tudor-SN contains non-canonical active-site sequences, we show that purified Tudor-SN exhibits nuclease activity similar to that of other staphylococcal nucleases. Notably, both purified Tudor-SN and RISC are inhibited by a specific competitive inhibitor of micrococcal nuclease. Tudor-SN is the first RISC subunit to be identified that contains a recognizable nuclease domain, and could therefore contribute to the RNA degradation observed in RNAi.

Expression of active monomeric and dimeric nuclease A from the gram-positive Streptococcus gordonii surface protein expression system.

We used the surface protein expression (SPEX) system to express an anchored and a secreted form of staphylococcal nuclease A (NucA) from gram-positive bacteria. NucA is a small ( approximately 18 kDa), extracellular, monomeric enzyme from Staphylococcus aureus. A deletion of amino acids 114-119 causes monomeric NucA to form homodimers. The DNA sequence encoding either wild-type or deletion mutant NucA was cloned via homologous recombination into Streptococcus gordonii. S. gordonii strains expressing either anchored or secreted, monomeric or dimeric NucA were isolated and tested for enzymatic activity using a novel fluorescence enzyme assay. We show that active monomeric and dimeric NucA enzyme can be expressed either anchored on the cell surface or secreted into the culture medium. The activity of the dimer NucA was approximately 100-fold less than the monomer. Secreted and anchored, monomeric NucA migrated on SDS-polyacrylamide gels at approximately 18 or approximately 30 kDa, respectively. In addition, similar to S. aureus NucA, the S. gordonii recombinant NucA enzyme was dependent on CaCl(2) and was heat stable. In contrast, however, the recombinant NucA activity was maximal at pH 7.0-7.5 whereas S. aureus NucA was maximal at pH 9.0. These results show, for the first time, expression of active enzyme and polymeric protein in secreted and anchored forms using SPEX. This further demonstrates the utility of this gram-positive surface protein expression system as a potential commensal bacterial delivery system for active, therapeutic enzymes, biopharmaceuticals, or vaccines.

Efficient production of recombinant brazzein, a small, heat-stable, sweet-tasting protein of plant origin.

Brazzein is a 54-amino-acid sweet-tasting protein first isolated from the fruit of Pentadiplandra brazzeana Baillon found in West Africa. Brazzein, as isolated from the fruit, is 500 times sweeter than sucrose on a weight basis (9500 times sweeter on a per-molecule basis). A minor component of brazzein from fruit, des-pGlu1-brazzein, has 53 amino acid residues and has twice the sweetness of the parent protein. We have designed a gene for des-pGlu1- brazzein that incorporates codons that are optimal for protein production in Escherichia coli. Production of brazzein from the chemically synthesized gene resulted in recombinant protein with sweetness similar to that of brazzein isolated from the original source. The best yields were achieved by producing brazzein as a fusion with staphylococcal nuclease with a designed cyanogen bromide cleavage site. Because of its intense sweetness and stability at high pH and temperature, brazzein is an ideal system for investigating the chemical and structural requirements involved in sweet-taste properties. This efficient protein production system for brazzein will facilitate such investigations.

An automated method for the detection of staphylococcal heat stable deoxyribonuclease in dairy products.

An automated sandwich immunoassay with specific polyclonal antibodies for the detection of Staphylococcus aureus thermostable nuclease (DNase) is described. To evaluate this assay, different quantities of purified S. aureus nuclease were added to dairy products. Additionally, staphylococcal counts and nuclease activity of milk samples inoculated with S. aureus were determined. Different extraction procedures were performed and compared. The results indicated that the automated test was a reliable method for detecting DNase activity in milk products. The procedure was completed in 2 h and detected 1 ng of DNase ml-1. Detection of the DNase was especially useful in cheeses and could be used to confirm positive enterotoxin results.

Isolation and physical characterization of random insertions in Staphylococcal nuclease.

Using genetic engineering techniques we generated randomly located internal tandem duplications of random size within Staphylococcal nuclease. Those insertions, possessing greater than 0.1% of normal activity, were sequenced and characterized physically. Insertions were found to begin and end in regions possessing secondary structure as well as in regions without secondary structure. All proteins remained folded and monomeric, although one mutant appeared, by both circular dichroism and size exclusion chromatography, to be partially unfolded. The stability of the insertions as assayed by guanidine hydrochloride denaturation ranged from nearly normal to destabilized by almost 4 kcal per mol. The activities of the insertion mutants ranged from 1/30 to 1/2000 of the parental nuclease.

The immunodominant region of Staphylococcal nuclease is represented by multiple peptide sequences.

Several published reports have lead to the characterization of naturally processed peptides that are presented in association with either class I or class II MHC molecules. Most peptides isolated from class II molecules are heterogeneous in length and exhibit ragged amino and carboxy termini. An intriguing finding was that one region of a molecule was often represented by many distinct peptides, rather than by a single dominant peptide species. Each of the peptides representing this dominant region exhibited a common core of amino acids, suggesting that this core may play a significant role in the binding of the peptide to class II and the recognition by peptide-specific T cells. Work from our laboratory has focused on the mechanisms involved in the immunodominance of antigenic determinants using the bacterial antigen Staphylococcal nuclease (Nase) as a model. Using truncated synthetic peptides, we have identified the immunodominant determinant of Nase to be located within the region 81-100 with a minimal antigenic core of 91-100 as determined. Addition of five residues to the carboxy terminus of this peptide had a negative effect on T cell recognition of this region. The present studies were undertaken in an effort to determine the sequence of the naturally processed immunodominant Nase determinant(s) presented in association with I-Ek class II. Our results indicate that the dominant region of the Nase molecule is represented by at least four distinct peptide species that are predicted to lie between residues 86 and 106 with a common core sequence of 91-96. These results indicate that the negative effects of flanking regions are dependent upon length and amino acid composition, and thus the use of truncated peptides to study minimal antigenic determinants may be misleading.

Testing the correlation between delta A and delta V of protein unfolding using m value mutants of staphylococcal nuclease.

The application of hydrostatic pressure to aqueous protein solutions results in the unfolding of the protein structure because the protein-solvent system volume is smaller for the unfolded state. Contributions to this decrease in volume upon unfolding (delta Vu) derive from altered interactions of the protein with solvent and are presumed to include electrostriction of charged residues, elimination of packing defects, and hydration of hydrophobic surfaces upon unfolding. If the contribution of hydrophobic surface area solvation to the observed volume change of unfolding were large and negative, as is generally assumed, then one would expect to find a correlation between the amount of surface area exposed on unfolding, delta A(u), and the volume change, delta Vu. In order to test this correlation, we have determined delta Vu for two mutants of staphylococcal nuclease, A69T + A90S and H121P, whose unfolding by denaturant is, respectively, either significantly more (28%) or significantly less (28%) cooperative than that observed for wild-type (WT). This cooperativity coefficient or m value has been shown to correlate with delta A(u). If, in turn, delta Vu is correlated with delta A(u), we would expect the m+ mutant, A69T + A90S, to exhibit a delta Vu that is more negative than WT nuclease, while the delta Vu for the m- mutant, H121P, should be smaller in absolute value. To verify the correlation between m value and delta A(u) for these mutants, we determined the xylose concentration dependence of the stability of each mutant at atmospheric pressure and as a function of pressure. The efficiency of xylose stabilization was found to be much greater for the m+ mutant than for WT, consistent with an increase in delta A(u), while that of the m- mutant was found to be only slightly greater than for WT, indicating that other factors may contribute to the denaturant m value in this case. Regardless of the denaturant m value or the effect of xylose on stability, the volume changes upon unfolding for both mutants were found to be within error of that observed for WT. Thus, there does not appear to be a correlation between the volume change and the change in exposed surface area upon unfolding. We have previously shown a lack of pH dependence of the volume change, ruling out electrostriction as a dominant contribution to delta Vu of nuclease. These studies implicate either compensation between polar and nonpolar hydration or excluded volume effects as the major determinant for the value of delta Vu.

Capillary electrophoresis of S. nuclease mutants.

The electrophoretic migration behavior of 12 S. nuclease variants from Staphylococcus aureus with small but well defined structural differences from site directed mutation was investigated in free solution capillary electrophoresis at pH 2.8 to 9.5. The nucleases are basic proteins; the pI and the M(r) of the wild type are 10.3 and 16.811 kd, respectively. With specially selected oligoamino buffers and with an inert, hydrophilic wall coating in 75 microns I.D. quartz capillary tubes, most of the proteins could be separated by CZE without interference by wall adsorption even at pH 9.5 where the selectivity was the highest. At pH 2.8, 4.1 and 7.0, S. nucleases are known to be in the random coil, "swollen" and the tight native state. Assuming that in a given state, i.e., at a certain pH, the molecular radii of the nucleases are the same, their hydrodynamic radii were calculated from their pertinent electrophoretic mobilities. The respective radii of 50.1, 26.8, and 25.0 Angstrum thus obtained agreed very well with the corresponding radii of gyration obtained from X-ray scattering. In fact, from the electrophoretic mobilities at pH 9.5, the existence of a hitherto unknown swollen basic state of the nuclease having a hydrodynamic radius of 30.5 Angstrum was postulated. In addition, a method was described to evaluate the valence of the protein at different pH from their pertinent electrophoretic mobilities. A general advantage of this method is that only the differences between the valences of the mutants and the wild type are needed; and for none of the proteins is required the knowledge of the actual valence. The results of the methods allowed the construction of a pH profile of the protein's valence. For the wild type, this profile was compared to the H+ titration curve and the agreement was excellent. Both methods employed some novel structure-electrophoretic mobility relationships and the predicted protein properties compared remarkably well to the values obtained by exoelectrophoretic methods such as pH titration and X-ray scattering. Surprisingly, certain S. nucleases having the same valence could also be readily separated by CZE in some cases under the same conditions used for the others. Close examination of appropriate X-ray crystallography and/or NMR data indicated subtle differences in the molecular structure of these proteins that could be responsible for slight alteration in their hydrodynamic radii.(ABSTRACT TRUNCATED AT 400 WORDS)

The production and X-ray structure determination of perdeuterated Staphylococcal nuclease.

Staphylococcal Nuclease (SNase) has been chosen as a model protein system to evaluate the improvement in neutron diffraction data quality using fully perdeuterated protein. Large quantities of the protein were expressed in Escherichia coli grown in medium containing deuterated amino acids and deuterated water (D2O) and then purified. The mean perdeuteration level of the non-exchangable sites in the protein was found to be 96% by electrospray ionization mass spectrometry. The perdeuterated enzyme was crystallized and its X-ray structure determined. Crystals of perdeuterated SNase have been grown to 1.5 mm3. Crystallization conditions, space group and cell parameters were found to be the same for both native and perdeuterated forms of the protein. Comparison of these two forms of SNase revealed no significant structural differences between them at the atomic resolution of 1.9 A. Data collection using crystals of the perdeuterated protein is scheduled at the Brookhaven High Flux Beam Reactor.

Resolution of proteins on a phenyl-Superose HR5/5 column and its application to examining the conformation homogeneity of refolded recombinant staphylococcal nuclease.

In order to examine the effect of amino acid substitutions on protein retention in hydrophobic interaction chromatography and the resolution of a phenyl-Superose HR5/5 column, two groups of staphylococcal nucleases, named Y113/W140 (wild-type), Y113W/W140 and Y113/W140F, Y113W/W140F, were produced by substituting tryptophan (W) for tyrosine (Y) at residue 113 and phenylalanine (F) for tryptophan (W) at residue 140. For each group, the proteins have the same amino acid at residue 140, but a different amino acid at residue 113. The solvent perturbation of nuclease fluorescence and 1,8-anilinoaphthalene-8-sulfonate binding studies showed that the substitutions do not change the side-chain positions of amino acids at residues 113 and 140. Chromatography of the proteins on the Phenyl-Superose HR5/5 column showed that the proteins with tryptophan at residue 113 have longer retention times than the proteins having tyrosine at residue 113; the proteins with the same amino acid at residue 113 have almost the same retention time regardless of substituting phenylalanine for tryptophan at residue 140. The studies clearly indicate that not all amino acid substitutions have an effect on protein retention; the contribution to retention of a given amino acid substitution depends on its position in a protein. Single amino acid substitutions at the exterior surface of a protein, which change the strength of hydrophobic interaction, can affect the protein retention in hydrophobic interaction chromatography. Staphylococcal nuclease and its mutants with only one amino acid difference on their surfaces can be discriminated by the phenyl-Superose column.(ABSTRACT TRUNCATED AT 250 WORDS)

Crystallization and preliminary X-ray analysis of an anti-staphylococcal nuclease-staphylococcal nuclease complex and of a second anti-staphylococcal nuclease antibody.

The Fab fragments of several monoclonal antibodies that bind Staphylococcal nuclease have been screened for crystallization conditions. Two of these, N10 and N25, have been crystallized in forms suitable for X-ray structural analysis. The anti-Staphylococcal nuclease antibody complex N10 Fab-nuclease crystallizes with symmetry consistent with space group C2 and cell parameters of a = 234.7 A; b = 43.5 A; c = 74.4 A; beta = 106.4 degrees. A second anti-Staphylococcal nuclease antibody, N25, although crystallized starting with the Fab-nuclease complex, apparently crystallizes as uncomplexed N25 Fab with symmetry consistent with space group P3(1)21 (or its enantiomorph P3(2)21) and cell parameters of a = b = 80.9 A; c = 138.4 A.

High-level expression of staphylococcal nuclease A in Escherichia coli.

The staphylococcal nuclease A gene has been successfully cloned and overexpressed in E. coli under the transcriptional control of the bacteriophage lambda PRPL promoters regulated by the temperature sensitive repressors. The SDS-PAGE analysis demonstrates that the nuclease A is produced to the extent of as much as 60% of the total cellular protein. The N-terminal analysis of the nuclease A shows that the amino terminal formyl methionine residue of the enzyme is precisely processed. The recombinant nuclease A with full activity is finally obtained after appropriate solubilization--denaturation and renaturation treatment. The conformational identity of the renatured nuclease A in different conditions is also studied by using hydrophobic interaction chromatography on a phenyl-superose HR5/5 column.

Structure and dynamics of staphylococcal nuclease mutants as studied by fluorescence quenching techniques.

Fluorescence techniques have been used to investigate the effect of mutations on the structure and dynamics of staphylococcal nuclease. An estimate of the accessibility to acrylamide of the enzyme's single tryptophan residue (Trp140) was obtained from the Stern-Volmer constant for fluorescence quenching. This was indicative of a partially buried tryptophan in the wild-type nuclease. Five single-site mutant nucleases (H124L, V66L, G88V, G79S and F76V) and one double mutant (V66L + G88V), with widely differing stabilities to denaturants, gave Stern-Volmer constants which were very similar to that of their parent enzyme. Studies of the temperature- and viscosity-dependence of quenching suggest that access by acrylamide to Trp140 is limited by diffusion rather than by protein structural fluctuations. Lifetime-resolved fluorescence anisotropy studies using steady-state instrumentation suggest that there is very little segmental motion of the Trp140; most of the anisotropy therefore decays due to protein rotation in the solution. Rotational correlation times for several nuclease mutants have been determined and these are very similar to that of the native nuclease. Thus it appears that these substitutions in the primary amino acid sequence, which have significant effects on the stability of the folded proteins, do not cause a significant change in the protein structure or dynamics around Trp140.