Sensitivity of the acoustic waveguide biosensor to protein binding as a function of the waveguide properties

The aim of this work is to study the effect of operating frequency, piezoelectric substrate and waveguide layer thickness on the sensitivity of the acoustic waveguide sensor during the specific binding of an antibody by a protein. Shear horizontal (SH) wave devices consisting of (a) a LiTaO3 substrate operating at 104 MHz, (b) a quartz substrate operating at 108 MHz and (c) a quartz substrate operating at 155 MHz were coated with a photoresist polymer layer in order to produce acoustic waveguide devices supporting a Love wave. The effect of the thickness of the polymer layer on the Love wave was assessed by measuring the amplitude and phase of the wave before and after coating. The sensitivity of the above three biosensors was compared during the detection of the specific binding of different concentrations of Immunoglobulin G in the range of 0.7-667 nM to a protein A modified surface. Results indicate that the thickness of the polymer guiding layer is critical for obtaining the maximum sensitivity for a given geometry but a trade-off has to be made between the theoretically determined optimum thickness for waveguiding and the device insertion loss. It was also found that increasing the frequency of operation results in a further increase in the device sensitivity to protein detection.     

A contactless surface acoustic wave biosensor.

Surface acoustic wave sensors operating in liquid generally cause problems resulting from wire bonding. The authors present an approach for a biosensor where the need for bonding wires is eliminated by utilizing inductive coupling of the sensor device to the RF circuitry. Protection of the electrodes from the liquid is achieved by coating the device surface with a SiO2 layer, resulting in a simplified handling of the devices. The first measurements with a sensor operating at 420 MHz are presented, demonstrating the potential of this operating principle for biosensing.     

Pulse mode shear horizontal-surface acoustic wave (SH-SAW) system for liquid based sensing applications

In this work, we describe a novel pulse mode shear horizontal-surface acoustic wave (SH-SAW) polymer coated biosensor that monitors rapid changes in both amplitude and phase. The SH-SAW sensors were fabricated on 36 degrees rotated Y-cut X propagating lithium tantalate (36 YX.LT). The sensitivity of the device to both mass loading and visco-elastic effects may be increased by using a thin guiding layer of cross-linked polymer. Two acoustic modes are excited by the electrodes in this crystalline direction. Metallisation of the propagation path of the 36 YX.LT devices allows the two modes to be discriminated. Successive polymer coatings resulted in the observation of resonant conditions in both modes as the layer thickness was increased. Using the 36 YX.LT devices, we have investigated the application of a novel pulse mode system by sensing a sequence of deposition and removal of a biological layer consisting of vesicles of the phospholipid POPC. A continuous wave system was used to verify the accuracy of the pulse mode system by sensing a series of poly(ethylene glycol) (PEG) solutions. The data clearly demonstrates the ability of the 36 YX.LT pulse mode system to provide rapid measurements of both amplitude and phase for biosensing applications.     

Gravimetric biosensors based on acoustic waves in thin polymer films

Most gravimetric biosensors use thin piezoelectric quartz crystals, either as resonating crystals (quartz crystal microbalance, QCM), or as bulk/surface acoustic wave (SAW) devices. In the majority of these the mass response is inversely proportional to the crystal thickness which, at a limit of about 150 microns, gives inadequate sensitivity. A new system is described in which acoustic waves are launched in very thin (10 microns) tensioned polymer films to produce an oscillatory device. A theoretical equation for this system is almost identical to the well-known Sauerbrey equation used in the QCM method. Because the polymer films are so thin, a 30-fold increase in sensitivity is predicted and verified by adding known surface masses. Temperature sensitivity is a problem so a separate control sensor and careful temperature regulation are necessary. Preliminary results showing the real time binding of protein (IgG), a step towards immunosensor development, and the use of mass enhancing particles are presented. Inexpensive materials are used so disposable gravimetric biosensors may become feasible.     

Multipurpose Love acoustic wave immunosensor for bacteria,virus or proteins detection

A multipurpose Love acoustic wave biosensor is described in this article. As mass loading is one of the main effect involved in acoustic wave sensors, a great range of biomolecules could be detected using such sensors. In this way, the antibody/antigen binding property was used to immobilise the target species. We first compared different coupling agents to link the antibodies sensitive layer to the SiO₂ sensor surface. Results showed that GPTS monolayer, allowing covalent attachment of antibodies bioreceptors, is better suited than DTSP and protein G. It permits to obtain a dense, stable and reproducible sensitive layer of antibodies. Then, different biological species with different size and shape like proteins, bacteriophages or bacteria were detected using such sensor. Different models have been chosen to validate the effective detection of a large species range: an anti-mouse antibody has been used to simulate small molecules (< 10 nm) like proteins or toxins, bacteriophage M13 for species lower than 1 μm like virus, and Escherichia coli for bacteria which are typically longer than 1 μm. Each kind of species were successfully quickly detected from few seconds for small proteins to one hour for bacteria, with detection threshold down to 4 ng/mm² for protein and 10⁶ cfu per milliliter for bacteria.     

Involvement of colicin in the limited protection of the colicin producing cells against bacteriophage

The restriction/modification system is considered to be the most common machinery of microorganisms for protection against bacteriophage infection. However, we found that mitomycin C induced Escherichia coli containing ColE7-K317 can confer limited protection against bacteriophage M13K07 and lambda infection. Our study showed that degree of protection is correlated with the expression level of the ColE7 operon, indicating that colicin E7 alone or the colicin E7-immunity protein complex is directly involved in this protection mechanism. It was also noted that the degree of protection is greater against the single-strand DNA bacteriophage M13K07 than the double-strand bacteriophage(lambda). Coincidently, the K(A) value of ColE7-Im either interacting with single-strand DNA (2.94x10(5)M(-1)) or double-strand DNA (1.75x10(5)M(-1)) reveals that the binding affinity of ColE7-Im with ssDNA is 1.68-fold stronger than that of the protein complex interacting with dsDNA. Interaction between colicin and the DNA may play a central role in this limited protection of the colicin-producing cell against bacteriophages. Based on these observations, we suggest that the colicin exporting pathway may interact to some extent with the bacteriophage infection pathway leading to a limited selective advantage for and limited protection of colicin-producing cells against different bacteriophages.     

Study of robustness of filamentous bacteriophages for industrial applications

The development of a whole new class of industrial agents, such as biologically based nanomaterials and viral vectors, has raised many challenges for their large-scale manufacture, principally due to the lack of essential physical data and bioprocessing knowledge. A new example is the promise of filamentous bacteriophages and their derivatives. As a result, there is now an increasing need for the establishment of strong biochemical engineering foundations to serve as a guide for future manufacture. This article investigates the effect of high-energy fluid flow on filamentous bacteriophage M13 to determine its robustness for large-scale processing. By the application of well-understood ultra scale-down predictive techniques, the viability of bacteriophage M13 was studied as a measure of its robustness and as a function of energy dissipation rate and fluid conditions. These experiments suggested that despite being perceived as a relatively fragile molecule in the literature, bacteriophage M13 should tolerate processing conditions in existing large-scale equipment designs. No loss of viability was noted up to a maximum energy dissipation rate of 2.9 × 10(6) W kg(-1) . Furthermore, significant losses above this threshold only occurred over periods well in excess of the exposure times expected in a bioprocess environment. Filamentous bacteriophages may therefore be regarded as a viable process material for industrial applications.     

Relation between the Yersinia phage and bacteriophages isolated from the environment

The bacteriophage designated RD2 has been isolated from the sewage in Rostov-on-Don city and studied. The morphology of bacteriophage particles and the biological properties of the bacteriophage make it related to the plague bacteriophage isolated by D'Errel. The molecular masses of the compared bacteriophages are almost identical being 26.4 +/- 0.4 Md for RD2 and 24.7 +/- 0.2 Md for D'Errel bacteriophage. The DNAs of the bacteriophages share 80% of homology and possess 15 nonhomologous regions scattered along the genomes. The phages are serologically related. The DNAs of both bacteriophages give the similar pattern of hydrolysis by restriction endonuclease EcoRV, but have the different sensitivity to many other restriction endonucleases. The protein specter of bacteriophage RD2 contains 18 polypeptides (11 minor ones), while the one of D'Errel bacteriophage contains 7 polypeptides similar in molecular mass with the polypeptides of RD2. The bacteriophage RD2 cannot be considered one of the plague causative agents of bacteriophages since the region where it has been isolated has a long epidemiological and epizootical record of absence of plague.     

A simple, rapid and sensitive presence/absence detection test for bacteriophage in drinking water

R. ARMON AND Y. KOTT. 1993. A rapid, simple and sensitive direct bacteriophage presence detection method for 500 ml drinking water samples has been developed. The method includes a glass device consisting of a jar containing the water sample and an immersible probe filled with solidified soft agar containing bacterial host cells. Host bacteria in logarithmic phase were added to the experimental volume and the probe was submerged. The entire device was incubated in a water bath at 36C.
Plaques of somatic bacteriophage infecting Escherichia coli strain CN₁₃, could be detected within 3 h. Male-specific bacteriophages infecting E. coli F+ amp were detected within 6 h. Bacteriophage infecting the anaerobe Bacteroides fragilis subsp. fragilis HSP40 were detected after 8 h. Application of this device and the associated technique, enabled a one-step detection of 1 pfu of E. coli or Bact. fragilis specific bacteriophage in 500 ml drinking water samples.     

Assembly of multimeric phage nanostructures through leucine zipper interactions

One barrier to the construction of nanoscale devices is the ability to place materials into 2D- and 3D-ordered arrays by controlling the assembly and ordering of connections between nanomaterials. Ordered assembly of nanoscale materials may potentially be achieved using biological tools that direct specific connections between individual components. Recently, viruses were successfully employed as scaffolds for the nucleation of nanoparticles and nanowires (Mao et al., 2004); however, there is a paucity of methods for the higher order assembly of phage-templated materials. Here we describe a general strategy for the assembly of filamentous bacteriophages into long, wire-like or into tripod-like structures. To prepare the linear phage assemblies, dimeric leucine zipper protein domains, fused to the p3 and p9 proteins of M13 bacteriophage, were employed to direct the specific end-to-end self-association of the bacteriophage particles. Electron microscopy revealed that up to 90% of the phage displaying complementary leucine zipper domains formed linear multi-phage assemblies, composed of up to 30 phage in length. To prepare tripod-like assemblies, phage were engineered to express trimeric leucine zippers as p3 fusion proteins. This resulted in 3D assembly with three individual phages attached at a single point. These ordered phage structures should provide a foundation for self-assembly of virally templated nanomaterials into useful devices.     

Succession of Streptococcus bovis strains with differing bacteriophage sensitivities in the rumens of two fistulated sheep.

The bacteriophage sensitivity of the Streptococcus bovis population resident in the rumens of two fistulated sheep was monitored for 112 days. During this time, three changes in the bacteriophage sensitivity of S. bovis occurred in the absence of detectable bacteriophages. Identical changes in bacteriophage sensitivity occurred simultaneously in both animals and, except for the relatively short periods of changeover in phage sensitivity, the S. bovis population in the rumens of the two sheep was homogeneous with respect to phage sensitivity.     

Succession of Streptococcus bovis strains with differing bacteriophage sensitivities in the rumens of two fistulated sheep.

The bacteriophage sensitivity of the Streptococcus bovis population resident in the rumens of two fistulated sheep was monitored for 112 days. During this time, three changes in the bacteriophage sensitivity of S. bovis occurred in the absence of detectable bacteriophages. Identical changes in bacteriophage sensitivity occurred simultaneously in both animals and, except for the relatively short periods of changeover in phage sensitivity, the S. bovis population in the rumens of the two sheep was homogeneous with respect to phage sensitivity.     

Comparison of two filtration-elution procedures to improve the standard methods ISO 10705-1 & 2 for bacteriophage detection in groundwater, surface water and finished water samples

Aim: To select a reliable method for bacteriophage concentration prior detection by culture from surface water, groundwater and drinking water to enhance the sensitivity of the standard methods ISO 10705‐1 & 2. Methods and Results: Artificially contaminated (groundwater and drinking water) and naturally contaminated (surface water) 1‐litre samples were processed for bacteriophages detection. The spiked samples were inoculated with about 150 PFU of F‐specific RNA bacteriophages and somatic coliphages using wastewater. Bacteriophage detection in the water samples was achieved using the standard method without and with a concentration step (electropositive Anodisc membrane or a pretreated electronegative Micro Filtration membrane, MF). For artificially contaminated matrices (drinking and ground waters), recovery rates using the concentration step were superior to 70% whilst analyses without concentration step mainly led to false negative results. Besides, the MF membrane presented higher performances compared with the Anodisc membrane. Conclusion: The concentration of a large volume of water (up to one litre) on a filter membrane avoids false negative results obtained by direct analysis as it allows detecting low number of bacteriophages in water samples. Significance and Impact of the Study: The addition of concentration step before applying the standard method could be useful to enhance the reliability of bacteriophages monitoring in water samples as bio‐indicators to highlight faecal pollution.     

Isolation, characterization of bacteriophages specific to Microlunatus phosphovorus and their application for rapid host detection

AIMS: To isolate and characterize lytic-bacteriophages specific to Microlunatus phosphovorus, and prepare fluorescently labelled phages (FLPs) for the rapid detection of the host bacterium in activated sludge. METHODS AND RESULTS: Isolation of bacteriophages lytic to M. phosphovorus was attempted by applying supernatants of activated sludge processes on the lawn of M. phosphovorus JCM9379 for plaque formation. Thirteen bacteriophage isolates were obtained. The restriction fragment length polymorphism analysis distinguished them into two different bacteriophages designated as phiMP1 and phiMP2. They were found to possess double-stranded DNA and host specificity. Morphological observations were done by electron microscopy. The bacteriophage particles stained by SYBR Green I was shown to be applicable to detect their host bacterial cells mixed with activated sludge. CONCLUSIONS: Two M. phosphovorus-specific bacteriophages were isolated and classified as Siphoviridae. FLPs of them were prepared, and successfully applied to detect the host bacterium added into the activated sludge. SIGNIFICANCE AND IMPACT OF THE STUDY: At least some of bacteria in activated sludge are susceptible to their related bacteriophages. Bacteriophages lytic to activated sludge bacteria could be affecting the bacterial population in activated sludge. The FLPs could be used for the easy-rapid detection of their host bacterium in activated sludge.     

Two-triplet CGA repeats impede DNA replication in bacteriophage M13 in Escherichia coli

Expansion and contraction instabilities associated with CAG, CGG, GAA and CGA (GAC) repeats propagation cause more than a dozen human genetic diseases and cancers. In this work, the propagation behavior of a bacteriophage M13 carrying a calf prochymosin cDNA fragment with a (CGA)2 repeat in a small hairpin forming region is reported. Such a M13 derivative when propagated in Escherichia coli, produces small plaques by decreasing phage yield and also mitigates the inhibition on host cell growth, compared to those control bacteriophages either containing a "CTGCTA" sequence or wildtype, suggesting that CGA2 repeat impedes DNA replication in vivo. Moreover, an increased internal free energy is found associated with (CGA)2 sequence compared to those "CTGCTA" and wildtype, which ruled out a possibility of CGA2 repeat effects on propagation is through influencing the hairpin structure formation.     

Silicon photonic crystal nanocavity-coupled waveguides for error-corrected optical biosensing

A photonic crystal (PhC) waveguide based optical biosensor capable of label-free and error-corrected sensing was investigated in this study. The detection principle of the biosensor involved shifts in the resonant mode wavelength of nanocavities coupled to the silicon PhC waveguide due to changes in ambient refractive index. The optical characteristics of the nanocavity structure were predicted by FDTD theoretical methods. The device was fabricated using standard nanolithography and reactive-ion-etching techniques. Experimental results showed that the structure had a refractive index sensitivity of 10(-2) RIU. The biosensing capability of the nanocavity sensor was tested by detecting human IgG molecules. The device sensitivity was found to be 2.3±0.24×10(5) nm/M with an achievable lowest detection limit of 1.5 fg for human IgG molecules. Additionally, experimental results demonstrated that the PhC devices were specific in IgG detection and provided concentration-dependent responses consistent with Langmuir behavior. The PhC devices manifest outstanding potential as microscale label-free error-correcting sensors, and may have future utility as ultrasensitive multiplex devices.     

Production in Saccharomycescerevisiae of MS2 virus-like particles packaging functional heterologous mRNAs

Recently, DNA bacteriophages (M13, lambda) have been genetically engineered to transfer genes into mammalian cells. Although efficiencies observed are still relatively low, this opens the possibility of using these viruses as a new class of transfection agents not only for fundamental research purposes but also in gene therapy protocols or in other applications like vaccination. In this respect, it has been shown that a lambda bacteriophage engineered to express the hepatitis B surface antigen in mammalian cells could elicit an immune response against this antigen in mice and rabbits without any specific targeting of the bacteriophage. These impressive results would be even more encouraging if they could be obtained with an RNA bacteriophage, as RNA vaccines are preferred over DNA vaccines for safety reasons. Up to now, RNA bacteriophages have never been engineered for gene delivery. In this paper, we have sought to determine whether such a vector could be obtained by engineering the RNA bacteriophage MS2. We show that MS2 can be produced as virus-like particles (VLPs) in Saccharomyces cerevisiae and is able to package functional heterologous mRNAs, provided that these mRNAs contain the MS2 packaging sequence. For instance, linking the MS2 packaging sequence to the human growth hormone (hGH) mRNA enabled the packaging of this particular mRNA in MS2 VLPs. Functionality in eukaryotic systems of packaged mRNAs was confirmed by showing that mRNAs purified from VLPs can be efficiently translated in vitro and in cell cultures. The high stability of MS2 could, therefore, make MS2 VLPs a very powerful carrier for RNA vaccines.     

Determination of the survival of bacteriophage M13 from chemical and physical challenges to assist in its sustainable bioprocessing

Bacteriophages are naturally infectious particles that replicate extremely efficiently in their bacterial hosts. Consequently, a facility processing bioproducts from a bacterial strain would be typically expected to focus on avoiding bacteriophage contamination. However, bacteriophages themselves are now showing great promise as a whole new class of industrial agents, such as biologically based nano-materials, delivery vectors and antimicrobials. This therefore raises a new challenge for their large-scale manufacture, potentially in contracted facilities shared with the host organism. The key issue is that knowledge of individual bacteriophage behaviour in the face of physical and chemical challenges is frequently incomplete, complicating decision-making regarding their safe introduction to a facility. This study tackles this issue for the filamentous bacteriophage M13. It was found that experimentation to determine an effective decontamination agent was important: Two of the three tested were ineffective. Virkon was considered to be the disinfectant of choice. Bacteriophage M13 was confirmed to be highly desiccation resistant, exhibiting a half-life of up to 120 days. Conversely, it was completely inactivated by strongly acidic and alkaline conditions and by temperatures above 95°C. By understanding the response of a bacteriophage to these challenges, steps towards their sustainable manufacture can be achieved.     

Nucleotide sequences in bacteriophage f1 DNA: nucleotide sequence of genes V, VII, and VIII.

The sequence of nucleotides comprising genes V, VII, and VIII of bacteriophage f1 was determined. The sequence was found to differ from that of the corresponding region of the related fd genome by eight base substitutions in gene V and one in gene VIII. The structure of gene VII was completely conserved between these two viruses and was identical to that of bacteriophage M13. Both transitions and transversions were found in cases where bases were substituted, but all substitutions were in the third codon position and had no effect on the structure of the corresponding protein product. The gene V protein product could thus be deduced to be identical to that of the corresponding proteins from bacteriophages fd and M13. A potential EcoRII cleavage site was formed by nucleotides 172 to 176 of gene V. Replicative form DNA form DNA from bacteriophage f1 is normally resistant to this enzyme, and evidence is presented to suggest that the sequence was modified through methylation of cytosine 173. The probable locations of other modified nucleotides in the sequence are discussed.     

Dual-mode thin film bulk acoustic wave resonators for parallel sensing of temperature and mass loading

Thin film bulk acoustic wave resonator (FBAR) devices supporting simultaneously multiple resonance modes have been designed for gravimetric sensing. The mechanism for dual-mode generation within a single device has been discussed, and theoretical calculations based on finite element analysis allowed the fabrication of FBARs whose resonance modes have opposite reactions to temperature changes; one of the modes exhibiting a positive frequency shift for a rise of temperature whilst the other mode exhibits a negative shift. Both modes exhibit negative frequency shift for a mass load and hence by monitoring simultaneously both modes it is possible to distinguish whether a change in the resonance frequency is due to a mass load or temperature variation (or a combination of both), avoiding false positive/negative responses in gravimetric sensing without the need of additional reference devices or complex electronics.