Water-Dispersible Three-Dimensional LC-Nanoresonators

Nanolithography techniques enable the fabrication of complex nanodevices that can be used for biosensing purposes. However, these devices are normally supported by a substrate and their use is limited to in vitro applications. Following a top-down procedure, we designed and fabricated composite inductance-capacitance (LC) nanoresonators that can be detached from their substrate and dispersed in water. The multimaterial composition of these resonators makes it possible to differentially functionalize different parts of the device to obtain stable aqueous suspensions and multi-sensing capabilities. For the first time, we demonstrate detection of these devices in an aqueous environment, and we show that they can be sensitized to their local environment and to chemical binding of specific molecular moieties. The possibility to optically probe the nanoresonator resonance in liquid dispersions paves the way to a variety of new applications, including injection into living organisms for in vivo sensing and imaging.     

ATP; related nucleotides and adenosine on neurotransmission.

The role of ATP on bioenergetics has long been well known. The chemical energy of ATP is then used to perform the chemical (synthesis of cellular components), mechanical (muscular contraction and cell movements) and osmotic (pumps for the active transport) work of the cells [see ref. (1)]. In relation to these functions ATP affects neuronal activities. Nevertheless recently ATP has been progressively implicated as being itself a neurotransmitter or at least modulating or vehiculating in some part the release of neurotransmitters. Such function was described for smooth muscle where ATP was suggested as the neurotransmitter of a non-cholinergic and non-adrenergic nerve ending, i.e. of a so called purinergic nerve [see ref. (2)]. For a recent account of ATP and nerve endings in the smooth muscle consult the excellent review by Burnstock (2).     

Characterization of membrane calcium pumps by simultaneous immunoblotting and 32P radiography

Calcium pumps of various plasma membrane, endoplasmic reticulum and sarcoplasmic reticulum preparations were visualized by simultaneous immunoblotting and autoradiography of the 32P-labelled phosphoenzymes. The pump proteins and their fragments produced by a proteolytic pretreatment of the membranes were selectively phosphorylated by [gamma-32P]ATP, separated on an acidic SDS-polyacrylamide gel, blotted onto nitrocellulose and reacted with polyclonal antibodies raised against the purified human erythrocyte and rat skeletal muscle sarcoplasmic reticulum calcium pumps, respectively. The immuno-reaction was detected by peroxidase staining, while the phosphoproteins were shown by autoradiography of the same blot. An antibody against the erythrocyte calcium pump, reacting on the blot with the 140 kDa erythrocyte calcium pump and its 80 kDa proteolytic fragment, did not show a cross-reaction with the calcium pump of similar molecular mass in rat synaptosome membranes or with any of the endoplasmic- or sarcoplasmic-type calcium pumps. An anti-sarcoplasmic reticulum calcium pump antibody cross reacted with several sarcoplasmic and endoplasmic calcium pump proteins and their proteolytic fragments but with none of the plasma membrane pumps. This sensitive double-labelling method can be applied to study structural relationships and molecular alterations in various ion pump proteins.     

Switchable DNA-origami nanostructures that respond to their environment and their applications

Structural DNA nanotechnology, in which Watson-Crick base pairing drives the formation of self-assembling nanostructures, has rapidly expanded in complexity and functionality since its inception in 1981. DNA nanostructures can now be made in arbitrary three-dimensional shapes and used to scaffold many other functional molecules such as proteins, metallic nanoparticles, polymers, fluorescent dyes and small molecules. In parallel, the field of dynamic DNA nanotechnology has built DNA circuits, motors and switches. More recently, these two areas have begun to merge—to produce switchable DNA nanostructures, which change state in response to their environment. In this review, we summarise switchable DNA nanostructures into two major classes based on response type: molecular actuation triggered by local chemical changes such as pH or concentration and external actuation driven by light, electric or magnetic fields. While molecular actuation has been well explored, external actuation of DNA nanostructures is a relatively new area that allows for the remote control of nanoscale devices. We discuss recent applications for DNA nanostructures where switching is used to perform specific functions—such as opening a capsule to deliver a molecular payload to a target cell. We then discuss challenges and future directions towards achieving synthetic nanomachines with complexity on the level of the protein machinery in living cells.     

Membrane-associated nanomotors for macromolecular transport

Nature has endowed cells with powerful nanomotors to accomplish intricate mechanical tasks, such as the macromolecular transport across membranes occurring in cell division, bacterial conjugation, and in a wide variety of secretion systems. These biological motors couple the chemical energy provided by ATP hydrolysis to the mechanical work needed to transport DNA and/or protein effectors. Here, we review what is known about the molecular mechanisms of these membrane-associated machines. Sequence and structural comparison between these ATPases reveal that they share a similar motor domain, suggesting a common evolutionary ancestor. Learning how these machines operate will lead the design of nanotechnology devices with unique applications in medicine and engineering.     

Cell ATP level of Saccharomyces cerevisiae sensitively responds to culture growth and drug-inflicted variations in membrane integrity and PDR pump activity

Cellular ATP level in Saccharomyces cerevisiae was measured during culture growth of strain US50-18C overproducing all major PDR pumps and its isogenic mutants variously deleted in these pumps. It was found to be inversely proportional to the intensity of cell metabolism during different growth phases and to the activity of PDR pumps, which are thus among major ATP consumers in the cells. The ATP level was increased when membrane integrity was affected by 0.5% butanol, and further increased by compound 23.1, a semisynthetic phenol lipid derivative that acts as inhibitor of Pdr5p and Snq2p pumps. The magnitude of increase in cell ATP caused by inhibition of Pdr5p pump by compound 23.1 and the Pdr5p pump inhibitor FK506 used for comparison reflects the activity and hence the energy demand of the pump. The rise in cell ATP caused by different PDR pump inhibitors can be thus used as an indicator of pump activity and the potency of the inhibitor.     

Proteomics, nanotechnology and molecular diagnostics

Sequencing of the human genome opened the way to the exploration of the proteome and this has lead to the identification of large numbers of proteins in complex biological samples. The identification of diagnostic patterns in samples taken from patients to aid diagnosis is in the early stages of development. The solution to many of the technical challenges in proteomics and protein based molecular diagnostics will be found in new applications of nanomaterials. This review describes some of the physical and chemical principles underlying nanomaterials and devices and outlines how they can be used in proteomics; developments which are establishing nanoproteomics as a new field. Nanoproteomics will provide the platform for the discovery of next generation biomarkers. The field of molecular diagnostics will then come of age.     

pH-responsive, DNA-directed reversible assembly of graphene oxide

Both graphene oxide (GO) and DNA can be used as building blocks for nano/micro devices or hybrid structures. Reversible assembly of these nanomaterials is highly desirable because of their promising applications in chemical sensors, energy storage, catalysis, and optoelectronic applications. However, reversible assembly of GO-DNA hybrid materials has not been achieved based on specific DNA hybridization and conformational transition. Here we report a general pH-responsive, DNA-directed assay for the design of a reversible assembly of GO-GO and GO-AuNPs hybrid using human telomeric G-quadruplex and i-motif DNA.     

Inhibition of ion pump ATPase activity by 3'-O-(4-benzoyl)benzoyl-ATP (BzATP): assessment of BzATP as an active site-directed probe

The interaction of 3'-O-(4-benzoyl)benzoyl-ATP (BzATP) with the renal (Na+ + K+)-ATPase, the sarcoplasmic reticulum Ca-transport ATPase, and the gastric (H+ + K+)-ATPase has been investigated in order to determine whether BzATP is a suitable probe for the labeling and identification of a peptide from the ATP binding sites of these ion pumps. After ultraviolet irradiation BzATP inhibited the enzymatic hydrolysis of ATP by each of the ion pumps, and also was covalently incorporated into the 100 000 dalton polypeptides of each protein. The presence of excess ATP in the reaction solution did not prevent either the inactivation of ATPase activity or the labeling of the catalytic polypeptides by BzATP. Prior modification of the ATPases with fluorescein-5'-isothiocyanate (FITC), however, prevented much of the labeling of the 100 000 dalton polypeptides by BzATP. BzATP competitively inhibited the high-affinity binding of ATP to the ion pumps, but ATP did not block the high-affinity binding of BzATP by the enzymes. BzATP binds to the membrane-bound ATPases at a high-affinity site with a Kd of 0.8-1.2 microM and a Bmax of 2-3 nmol/mg, and also binds to at least one low-affinity, high-capacity site on the membranes. HPLC separation of the soluble peptides from a tryptic digest of BzATP-labeled (Na+ + K+)-ATPase revealed the presence of several labeled peptides, none of which was protected by either ATP or FITC. Although BzATP can displace ATP from a high-affinity binding site on the ion pumps, it appears, therefore, that inactivation of enzymatic activity is the result of reactions between BzATP and the proteins at locations outside this site. Thus, it is concluded from these experiments that BzATP is not likely to be a useful probe for the ATP binding sites on the ion transport ATPases.     

A model for coupling of H(+) and substrate fluxes based on "time-sharing" of a common binding site

Both prokaryotic and eukaryotic cells contain an array of membrane transport systems maintaining the cellular homeostasis. Some of them (primary pumps) derive energy from redox reactions, ATP hydrolysis, or light absorption, whereas others (ion-coupled transporters) utilize ion electrochemical gradients for active transport. Remarkable progress has been made in understanding the molecular mechanism of coupling in some of these systems. In many cases carboxylic residues are essential for either binding or coupling. Here we suggest a model for the molecular mechanism of coupling in EmrE, an Escherichia coli 12-kDa multidrug transporter. EmrE confers resistance to a variety of toxic cations by removing them from the cell interior in exchange for two protons. EmrE has only one membrane-embedded charged residue, Glu-14, which is conserved in more than 50 homologous proteins. We have used mutagenesis and chemical modification to show that Glu-14 is part of the substrate-binding site. Its role in proton binding and translocation was shown by a study of the effect of pH on ligand binding, uptake, efflux, and exchange reactions. The studies suggest that Glu-14 is an essential part of a binding site, which is common to substrates and protons. The occupancy of this site by H(+) and substrate is mutually exclusive and provides the basis of the simplest coupling for two fluxes.     

Kinetics of the association/dissociation cycle of an ATP-binding cassette nucleotide-binding domain

Most ATP binding cassette (ABC) proteins are pumps that transport substrates across biological membranes using the energy of ATP hydrolysis. Functional ABC proteins have two nucleotide-binding domains (NBDs) that bind and hydrolyze ATP, but the molecular mechanism of nucleotide hydrolysis is unresolved. This is due in part to the limited kinetic information on NBD association and dissociation. Here, we show dimerization of a catalytically active NBD and follow in real time the association and dissociation of NBDs from the changes in fluorescence emission of a tryptophan strategically located at the center of the dimer interface. Spectroscopic and structural studies demonstrated that the tryptophan can be used as dimerization probe, and we showed that under hydrolysis conditions (millimolar MgATP), not only the dimer dissociation rate increases, but also the dimerization rate. Neither dimer formation or dissociation are clearly favored, and the end result is a dynamic equilibrium where the concentrations of monomer and dimer are very similar. We proposed that based on their variable rates of hydrolysis, the rate-limiting step of the hydrolysis cycle may differ among full-length ABC proteins.     

Structure and function of ATP-driven ion pumps Efraim Racker

ATP-driven ion pumps are used by cells to generate ion gradients at the expense of ATP hydrolysis or to generate ATP at the expense of an ion gradient. The pumps are of varying complexities containing between two and ten polypeptide chains.     

生物发光及化学发光在生物医学领域中应用的进展

生物发光和化学发光在生物医学领域内的应用主要包括细胞学检测,分子生物学、卫生学检测,生物传感器、脂质过氧化检测和药物筛选等六个方面,其中细胞学检测主要是利用细胞内ＡＴＰ导致的虫荧光素酶发光进行活细胞计数,目前已实现快速、动态、单细胞分析;同时发现了一些新的与生物或化学发光有关的细胞学指标。分子生物学领域内的应用主要为报告基因和分子杂交,近年来又有人推出了生物发光实时ＤＮＡ测序技术。卫生学检测则主要     

A Portable Chemotaxis Platform for Short and Long Term Analysis

Flow-based microfluidic systems have been widely utilized for cell migration studies given their ability to generate versatile and precisely defined chemical gradients and to permit direct visualization of migrating cells. Nonetheless, the general need for bulky peripherals such as mechanical pumps and tubing and the complicated setup procedures significantly limit the widespread use of these microfluidic systems for cell migration studies. Here we present a simple method to power microfluidic devices for chemotaxis assays using the commercially available ALZET® osmotic pumps. Specifically, we developed a standalone chemotaxis platform that has the same footprint as a multiwell plate and can generate well-defined, stable chemical gradients continuously for up to 7 days. Using this platform, we validated the short-term (24 hours) and long-term (72 hours) concentration dependent PDGF-BB chemotaxis response of human bone marrow derived mesenchymal stem cells.     

Synthetic, biofunctional nucleic acid-based molecular devices

Structural DNA nanotechnology seeks to create architectures of highly precise dimensions using the physical property that short lengths of DNA behave as rigid rods and the chemical property of Watson-Crick base-pairing that acts as a specific molecular glue with which such rigid rods may be joined. Thus DNA has been used as a molecular scale construction material to make molecular devices that can be broadly classified under two categories (i) rigid scaffolds and (ii) switchable architectures. This review details the growing impact of such synthetic nucleic acid based molecular devices in biology and biotechnology. Notably, a significant trend is emerging that integrates morphology-rich nucleic acid motifs and alternative molecular glues into DNA and RNA architectures to achieve biological functionality.     

Towards molecular computing: co-development of microfluidic devices and chemical reaction media

Microfluidics provides a powerful technology for both the production of molecular computing components and for the implementation of molecular computing architectures. The potential commercial applications of microfluidics drive rapid progress in this field-but at the same time focus interest on materials that are compatible with physiological aqueous conditions. For engineering applications that consider a broader range of physico-chemical conditions the narrow set of established materials for microfluidics can be a challenge. As a consequence of the large surface to volume ratio inherent in microfluidic technology the material of the device can greatly affect the chemistry in the channels of the device. In practice it is necessary to co-develop the chemical medium to be used in the device together with the microfluidic devices. We describe this process for a molecular computing architecture that makes use of excitable lipid-coated droplets of Belousov-Zhabotinsky reaction medium as its active processing components. We identify fluoropolymers with low melting temperature as a suitable substrate for microfluidics to be used in conjunction with Belousov-Zhabotinsky droplets in decane.     

Insights into how nucleotide supplements enhance the peroxidase-mimicking DNAzyme activity of the G-quadruplex/hemin system

Since the initial discovery of the catalytic capability of short DNA fragments, this peculiar enzyme-like property (termed DNAzyme) has continued to garner much interest in the scientific community because of the virtually unlimited applications in developing new molecular devices. Alongside the exponential rise in the number of DNAzyme applications in the last past years, the search for convenient ways to improve its overall efficiency has only started to emerge. Credence has been lent to this strategy by the recent demonstration that the quadruplex-based DNAzyme proficiency can be enhanced by ATP supplements. Herein, we have made a further leap along this path, trying first of all to decipher the actual DNAzyme catalytic cycle (to gain insights into the steps ATP may influence), and subsequently investigating in detail the influence of all the parameters that govern the catalytic efficiency. We have extended this study to other nucleotides and quadruplexes, thus demonstrating the versatility and broad applicability of such an approach. The defined exquisitely efficient DNAzyme protocols were exploited to highlight the enticing advantages of this method via a 96-well plate experiment that enables the detection of nanomolar DNA concentrations in real-time with the naked-eye (see movie as Supplementary Data).     

Targeted protein functionalization using His-tags

With the impressive growth in gene sequence data that has become available, recombinant proteins represent an increasingly vast source of molecular components, with unique functional and structural properties, for use in biotechnological applications and devices. To facilitate the use, manipulation, and integration of such molecules into devices, a controllable method for their chemical modification was developed. In this approach, a trifunctional labeling reagent first recognizes and binds a His-tag on the target protein's surface. After binding, a photoreactive group on the trifunctional molecule is triggered to create a covalent linkage between the reagent and the target protein. The third moiety on the labeling reagent can be varied to bring unique chemical functionality to the target protein. This approach provides: (1) specificity in that only His-tagged targets are modified, (2) regio-specific control in that the target is modified proximal to the His-tag, the position of which can be varied, and (3) stoichiometric control in that the number modifications is limited by the binding capacity of the His-tag. Two such labeling reagents were designed, synthesized, and used to modify both N- and C-terminally His-tagged versions of the enzyme murine dihydrofolate reductase (mDHFR). The first reagent biotinylated the enzyme,while the second served to attach an oligonucleotide to yield a protein-DNA conjugate. In all cases, modification in this manner brings new functionality to the protein while leaving the enzymatic activity intact. The protein-DNA conjugate was used to specifically immobilize the active enzyme through DNA hybridization onto polystyrene microspheres, a step toward creating a functional protein microarray.