Recent progress in magnetic nanoparticles and mesoporous materials for enzyme immobilization: an update

Enzymes immobilized onto substrates with excellent selectivity and activity show a high stability and can withstand extreme experimental conditions, and their performance has been shown to be retained after repeated uses. Applications of immobilized enzymes in various fields benefit from their unique characteristics. Common methods, including adsorption, encapsulation, covalent attachment and crosslinking, and other emerging approaches (e.g., MOFs) of enzyme immobilization have been developed mostly in recent years. In accordance with these immobilization methods, the present review elaborates the application of magnetic separable nanoparticles and functionalized SBA-15 and MCM-41 mesoporous materials used in the immobilization of enzymes.

The MocR/GabR Ectoine and Hydroxyectoine Catabolism Regulator EnuR: Inducer and DNA Binding

The compatible solutes ectoine and 5-hydroxyectoine are widely synthesized by bacteria as osmostress protectants. These nitrogen-rich tetrahydropyrimidines can also be exploited as nutrients by microorganisms. Many ectoine/5-hydroxyectoine catabolic gene clusters are associated with a regulatory gene (enuR: ectoine nutrient utilization regulator) encoding a repressor protein belonging to the MocR/GabR sub-family of GntR-type transcription factors. Focusing on EnuR from the marine bacterium Ruegeria pomeroyi, we show that the dimerization of EnuR is mediated by its aminotransferase domain. This domain can fold independently from its amino-terminal DNA reading head and can incorporate pyridoxal-5′-phosphate (PLP) as cofactor. The covalent attachment of PLP to residue Lys302 of EnuR was proven by mass-spectrometry. PLP interacts with system-specific, ectoine and 5-hydroxyectoine-derived inducers: alpha-acetyldiaminobutyric acid (alpha-ADABA), and hydroxy-alpha-acetyldiaminobutyric acid (hydroxy-alpha-ADABA), respectively. These inducers are generated in cells actively growing with ectoines as sole carbon and nitrogen sources, by the EutD hydrolase and targeted metabolic analysis allowed their detection. EnuR binds these effector molecules with affinities in the low micro-molar range. Studies addressing the evolutionary conservation of EnuR, modelling of the EnuR structure, and docking experiments with the inducers provide an initial view into the cofactor and effector binding cavity. In this cavity, the two high-affinity inducers for EnuR, alpha-ADABA and hydroxy-alpha-ADABA, are positioned such that their respective primary nitrogen group can chemically interact with PLP. Purified EnuR bound with micro-molar affinity to a 48 base pair DNA fragment containing the sigma-70 type substrate-inducible promoter for the ectoine/5-hydroxyectoine importer and catabolic gene cluster. Consistent with the function of EnuR as a repressor, the core elements of the promoter overlap with two predicted EnuR operators. Our data lend themselves to a straightforward regulatory model for the initial encounter of EnuR-possessing ectoine/5-hydroxyectoine consumers with environmental ectoines and for the situation when the external supply of these compounds has been exhausted by catabolism.

Mini Review: Structure and Function of Nematode Phosphorylcholine-Containing Glycoconjugates

An unusual aspect of the biology of nematodes is the covalent attachment of phosphorylcholine (PC) to carbohydrate in glycoconjugates. Investigation of the structure of these molecules by ever-increasingly sophisticated analytical procedures has revealed that PC is generally in phosphodiester linkage with C6 of N-acetylglucosamine (GlcNAc) in both N-type glycans and glycosphingolipids. Up to five PC groups have been detected in the former, being located on both antenna and core GlcNAc. The PC donor for transfer to carbohydrate appears to be phosphatidylcholine but the enzyme responsible for transfer remains to be identified. Work primarily involving the PC-containing Acanthocheilonema viteae secreted product ES-62, has shown that the PC attached to nematode N-glycans possesses a range of immunomodulatory properties, subverting for example, pro-inflammatory signalling in various immune system cell-types including lymphocytes, mast cells, dendritic cells and macrophages. This has led to the generation of PC-based ES-62 small molecule analogues (SMAs), which mirror the parent molecule in preventing the initiation or progression of disease in mouse models of a number of human conditions associated with aberrant inflammatory responses. These include rheumatoid arthritis, systemic lupus erythematosus and lung and skin allergy such that the SMAs are considered to have widespread therapeutic potential.

Development of Aptasensors for Steroidal Hormones

<p>Aptamers are synthetic nucleic acid single stranded (ss)DNAs or RNAs that can bind with high affinity and specificity to a broad range of targets, including proteins and low molecular weight molecules. This work presents the design, development and implementation of novel aptamer based sensors (aptasensors) for the detection of a target of environmental and medical significance - 17-β estradiol (E2). By combining a previously isolated E2 binding 75-mer ssDNA aptamer with a variety of different signal transducers, E2 was successfully detected and quantified below the environmental and biological relevant concentrations. By applying the same aptamer to different sensor formats, the advantages and disadvantages of each signal transduction mechanism were compared. Target-induced conformational switch within an aptamer molecule can be transduced via labelling different sections of the aptamer with pairs of fluorescent dyes or with a redox probe, however those strategies require detailed knowledge of specific aptamer conformations and target interaction sites. Herein, a label free method is developed - size based aptasensor described in Chapter 2. The new method only depends on the general property that small molecule binding aptamers adopt a more compact folded structure when they bind to their target. Dynamic light scattering (DLS) and tunable resistive pulse sensing (TRPS) were used to probe recognition events between E2 and aptamers conjugated to carboxylated polystyrene nanoparticles (NPs). Upon E2 recognition, a distinct reduction in size and a less negative surface potential of the conjugated particles were observed, which can be correlated to the concentration of E2 in the lower nanomolar range (as low as 5 nM). On-site monitoring of E2 requires rapid and sensitive screening methods with minimal instrumentation. Previously, gold nanoparticles (AuNPs) were exploited in the construction of colorimetric aptasensors for different targets. Aggregation assays produce colorimetric signals observed by naked-eye when target-bound aptamers dissociate from AuNP surfaces, triggering aggregation. However, it is unknown how the length of aptamer sequences affects their dissociation from AuNP surfaces and subsequent aggregation. Chapter 3 demonstrates the benefit of editing aptamer sequences with specific regard to the way signals are transduced in AuNP based colorimetric assays. The 20 flanking nucleotides to the 35-mer inner core of the parent 75-mer aptamer were eliminated. The 35-mer aptamer has a lower dissociation constant KD (14 nM vs. 25 nM), improved discrimination against other steroidal molecules and greatly improve the sensitivity for E2 detection from 5 nM to 200 pM. In fact, this simple strategy enabled facile detection of E2 in urine at 5 nM, approaching levels of biological relevance. There is a pressing demand for methods with accurate and rapid performance to detect and quantify E2, at levels comparable or even below the biological concentrations to eliminate pre-concentration and sample purification process. Existing electrochemical aptasensors feature DNA probes covalently tethered to various surfaces including gold and conducting polymer electrode. An electrochemical impedance spectroscopy (EIS) based sensor was created using nanoporous conducting polymer electrodes functionalized with the 75-mer aptamer. The one fM detection limit found is one order of magnitude lower than the recorded biological level. As a novel alternative approach, sensing electrodes were also created via the non-specific adsorption of the 35-mer onto Au and Au nanoparticle electrodes. This approach, described in Chapter 4, led to the same level of detection as the conducting polymer aptasensor, but via a mechanism with similarities to the colorimetric sensor. Non-specific adsorption of aptamers to Au was found to play additional favourable roles including self-passivation and stabilization of Au nanoparticle based electrodes. Sensing with this format might remove the need for laborious surface passivation with alkylthiol molecules encountered with the conventional covalent attachment of the DNAs through thiol-linkers. In general, the reported aptasensors provide efficient means to detect the steroidal molecule E2 as well as advance the understanding of aptasensors by comparing the performance of the same aptamer in various sensing platforms. Long aptamers sequences appeared to be more efficient in signal transduction when specific surface tethering is involved, as in the size-based assay, and the electrochemical assay with aptamers covalently tethered to the electrode. Here, the non-binding flanking nucleotides, i.e. nucleotides adjacent to the target binding pocket, appeared to amplify the sensing signals. However, shorter truncated sequences showed better performance when signal generation depends on surface dissociation of non-specifically adsorbed aptamer sequences, as in the colorimetric assay, and the electrochemical sensor constructed from adsorbed aptamers. These insights can be readily applied to aptasensors for the growing range of targets.</p>

Development of Aptasensors for Steroidal Hormones

<p>Aptamers are synthetic nucleic acid single stranded (ss)DNAs or RNAs that can bind with high affinity and specificity to a broad range of targets, including proteins and low molecular weight molecules. This work presents the design, development and implementation of novel aptamer based sensors (aptasensors) for the detection of a target of environmental and medical significance - 17-β estradiol (E2). By combining a previously isolated E2 binding 75-mer ssDNA aptamer with a variety of different signal transducers, E2 was successfully detected and quantified below the environmental and biological relevant concentrations. By applying the same aptamer to different sensor formats, the advantages and disadvantages of each signal transduction mechanism were compared. Target-induced conformational switch within an aptamer molecule can be transduced via labelling different sections of the aptamer with pairs of fluorescent dyes or with a redox probe, however those strategies require detailed knowledge of specific aptamer conformations and target interaction sites. Herein, a label free method is developed - size based aptasensor described in Chapter 2. The new method only depends on the general property that small molecule binding aptamers adopt a more compact folded structure when they bind to their target. Dynamic light scattering (DLS) and tunable resistive pulse sensing (TRPS) were used to probe recognition events between E2 and aptamers conjugated to carboxylated polystyrene nanoparticles (NPs). Upon E2 recognition, a distinct reduction in size and a less negative surface potential of the conjugated particles were observed, which can be correlated to the concentration of E2 in the lower nanomolar range (as low as 5 nM). On-site monitoring of E2 requires rapid and sensitive screening methods with minimal instrumentation. Previously, gold nanoparticles (AuNPs) were exploited in the construction of colorimetric aptasensors for different targets. Aggregation assays produce colorimetric signals observed by naked-eye when target-bound aptamers dissociate from AuNP surfaces, triggering aggregation. However, it is unknown how the length of aptamer sequences affects their dissociation from AuNP surfaces and subsequent aggregation. Chapter 3 demonstrates the benefit of editing aptamer sequences with specific regard to the way signals are transduced in AuNP based colorimetric assays. The 20 flanking nucleotides to the 35-mer inner core of the parent 75-mer aptamer were eliminated. The 35-mer aptamer has a lower dissociation constant KD (14 nM vs. 25 nM), improved discrimination against other steroidal molecules and greatly improve the sensitivity for E2 detection from 5 nM to 200 pM. In fact, this simple strategy enabled facile detection of E2 in urine at 5 nM, approaching levels of biological relevance. There is a pressing demand for methods with accurate and rapid performance to detect and quantify E2, at levels comparable or even below the biological concentrations to eliminate pre-concentration and sample purification process. Existing electrochemical aptasensors feature DNA probes covalently tethered to various surfaces including gold and conducting polymer electrode. An electrochemical impedance spectroscopy (EIS) based sensor was created using nanoporous conducting polymer electrodes functionalized with the 75-mer aptamer. The one fM detection limit found is one order of magnitude lower than the recorded biological level. As a novel alternative approach, sensing electrodes were also created via the non-specific adsorption of the 35-mer onto Au and Au nanoparticle electrodes. This approach, described in Chapter 4, led to the same level of detection as the conducting polymer aptasensor, but via a mechanism with similarities to the colorimetric sensor. Non-specific adsorption of aptamers to Au was found to play additional favourable roles including self-passivation and stabilization of Au nanoparticle based electrodes. Sensing with this format might remove the need for laborious surface passivation with alkylthiol molecules encountered with the conventional covalent attachment of the DNAs through thiol-linkers. In general, the reported aptasensors provide efficient means to detect the steroidal molecule E2 as well as advance the understanding of aptasensors by comparing the performance of the same aptamer in various sensing platforms. Long aptamers sequences appeared to be more efficient in signal transduction when specific surface tethering is involved, as in the size-based assay, and the electrochemical assay with aptamers covalently tethered to the electrode. Here, the non-binding flanking nucleotides, i.e. nucleotides adjacent to the target binding pocket, appeared to amplify the sensing signals. However, shorter truncated sequences showed better performance when signal generation depends on surface dissociation of non-specifically adsorbed aptamer sequences, as in the colorimetric assay, and the electrochemical sensor constructed from adsorbed aptamers. These insights can be readily applied to aptasensors for the growing range of targets.</p>

Hybrid Supercapacitor Electrode Materials via Molecular Imprinting of Nitrogenous Ligands and Iron Complexes into Carbon Support

Novel hybrid supercapacitor materials were made by the covalent immobilization of nitrogenous ligands onto the surface of commercial carbon support (Vulcan XC-72), then coordinated to iron. The covalent attachment of the nitrogenous ligands allows for the controlled deposition of nitrogen functionalities on the surface of the carbon. The supercapacitor tests in acidic media showed significant growth of the capacitance as a result of the nitrogenous ligands on the support. Notably, the increase of the capacitance values directly correlates with the molecular loading on the surface. Following coordination of the iron to the ligands on the surface further elevated the capacitance via Faradaic reactions of the metal center. Remarkably, the overall capacitance of materials significantly increased after the course of long-term cycling tests (ca. 110% or higher). At the beginning of durability studies, a small decline in capacitance was observed, due to some extent of molecular decomposition on the surface of the electrode. However, the intense cycling further propagates a steady growth of the overall capacitance. This could be attributed to the process of polymerization of physisorbed molecules/ radicals that result in the formation of a 3D network structure that eventually boosts the overall capacitance and charge storage of the electrode.