A percolation-type criticality threshold controls immune protein coating of surfaces.

When a material enters the body, it is immediately attacked by hundreds of proteins, organized into complex networks of binding interactions and reactions. How do such complex systems interact with a material, "deciding" whether to attack? We focus on the "complement" system of ∼40 blood proteins that bind microbes, nanoparticles, and medical devices, initiating inflammation. We show a sharp threshold for complement activation upon varying a fundamental material parameter, the surface density of potential complement attachment points.

A Robust and Efficient Method to Purify DNA-Scaffolded Nanostructures by Gravity-Driven Size Exclusion Chromatography.

In recent decades, nucleic acid self-assemblies have emerged as popular nanomaterials due to their programmable and robust assembly, prescribed geometry, and versatile functionality. However, it remains a challenge to purify large quantities of DNA nanostructures or DNA-templated nanocomplexes for various applications. Commonly used purification methods are either limited by a small scale or incompatible with functionalized structures.

Modulation of Enzyme Cascade Activity by Local Substrate Enrichment and Exclusion on DNA Nanostructures.

Substrate confinement and channeling play a critical role in multienzyme pathways and are considered to impact the catalytic efficiency and specificity of biomimetic and artificial nanoreactors. Here we reported a modulation of a multienzyme system with the cascade activity impacted by the surface affinity binding to substrate molecules. A DNA origami modified with aptamers was used to bind and enrich ATP molecules in the local area of immobilized enzymes, thereby enhancing the activity of an enzyme cascade by more than 2-fold.

DNA Nanoscaffolds for Multienzyme Systems Assembly.

Multienzyme reactions play an important role in cellular metabolic functions. The assembly of a metabolon is often observed, in which the position and the orientation of composite enzymes are optimized to facilitate the substrate transport. The recent progress of DNA nanotechnology is promising to organize the assembly of bimolecular complexes with precise controlled geometric patterns at nanoscale, such as enzyme cascades assembly, biomimetic substrate channeling, and compartmentalization.

Inactivation Kinetics of G-Quadruplex/Hemin Complex and Optimization for More Reliable Catalysis.

Reliable catalysis is critical for the synthesis of various chemicals, molecular sensing and biomedicine. G-quadruplex/Hemin (GQH) complex, a peroxidase-mimicking DNAzyme, has been widely used in various publications. However, a concern exists about the unstable kinetics of GQH-catalyzed peroxidation.

Rapid Nucleic Acid Reaction Circuits for Point-of-care Diagnosis of Diseases.

An urgent need exists for a rapid, cost-effective, facile, and reliable nucleic acid assay for mass screening to control and prevent the spread of emerging pandemic diseases. This urgent need is not fully met by current diagnostic tools. In this review, we summarize the current state-of-the-art research in novel nucleic acid amplification and detection that could be applied to point-of-care (POC) diagnosis and mass screening of diseases.

Reduction of Promiscuous Peptides-Enzyme Inhibition and Aggregation by Negatively Charged Biopolymers.

In this work, peptides selected from a microarray were found to inhibit β-gal with promiscuous mechanisms. Peptides inhibited the enzyme in a noncompetitive kinetics, and the inhibition of enzyme activities was reduced under high enzyme concentrations and the addition of detergent. Dynamic light scattering and atomic force microscope revealed that peptide/enzyme aggregation was related to inhibited enzyme activities.

DNA-Scaffolded Proximity Assembly and Confinement of Multienzyme Reactions.

Cellular functions rely on a series of organized and regulated multienzyme cascade reactions. The catalytic efficiencies of these cascades depend on the precise spatial organization of the constituent enzymes, which is optimized to facilitate substrate transport and regulate activities. Mimicry of this organization in a non-living, artificial system would be very useful in a broad range of applications-with impacts on both the scientific community and society at large.

Self-Assembly of DNA-Minocycline Complexes by Metal Ions with Controlled Drug Release.

Here we reported a study of metal ions-assisted assembly of DNA-minocycline (MC) complexes and their potential application for controlling MC release. In the presence of divalent cations of magnesium or calcium ions (M), MC, a zwitterionic tetracycline analogue, was found to bind to phosphate groups of nucleic acids via an electrostatic bridge of phosphate (DNA)-M-MC. We investigated multiple parameters for affecting the formation of DNA-Mg-MC complex, including metal ion concentrations, base composition, DNA length, and single- versus double-stranded DNA.

Biomimetic Compartments Scaffolded by Nucleic Acid Nanostructures.

The behaviors of living cells are governed by a series of regulated and confined biochemical reactions. The design and successful construction of synthetic cellular reactors can be useful in a broad range of applications that will bring significant scientific and economic impact. Over the past few decades, DNA self-assembly has enabled the design and fabrication of sophisticated 1D, 2D, and 3D nanostructures, and is applied to organizing a variety of biomolecular components into prescribed 2D and 3D patterns.

DNA-Mediated Proximity-Based Assembly Circuit for Actuation of Biochemical Reactions.

Smart nanodevices that integrate molecular recognition and signal production hold great promise for the point-of-care (POC) diagnostic applications. Herein, the development of a DNA-mediated proximity assembly of biochemical reactions, which was capable of sensing various bio-targets and reporting easy-to-read signals is reported. The circuit was composed of a DNA hairpin-locked catalytic cofactor with inhibited activity.

2D Enzyme Cascade Network with Efficient Substrate Channeling by Swinging Arms.

In living cells, compartmentalized or membrane-associated enzymes are often assembled into large networks to cooperatively catalyze cascade reaction pathways essential for cellular metabolism. Here, we report the assembly of an artificial 2D enzyme network of two cascade enzymes-glucose-6-phosphate dehydrogenase (G6PDH) and lactate dehydrogenase (LDH)-on a wireframe DNA origami template. Swinging arms were used to facilitate the transport of the redox intermediate of NAD /NADH between enzyme pairs on the array.

DNA-crowded enzyme complexes with enhanced activities and stabilities.

We present a robust and simple method to prepare DNA-crowded enzyme complexes by directly assembling long DNA duplexes on the enzyme surface. DNA-crowded enzyme complexes show boosted substrate turnover numbers, and increased stabilities against various storage conditions. They could be potentially scaled up for applications in biomaterials and biotechnology.

An activity transition from NADH dehydrogenase to NADH oxidase during protein denaturation.

A decrease in the specific activity of an enzyme is commonly observed when the enzyme is inappropriately handled or is stored over an extended period. Here, we reported a functional transition of an FMN-bound diaphorase (FMN-DI) that happened during the long-term storage process. It was found that FMN-DI did not simply lose its β-nicotinamide adenine diphosphate (NADH) dehydrogenase activity after a long-time storage, but obtained a new enzyme activity of NADH oxidase.

Computational and experimental analysis of short peptide motifs for enzyme inhibition.

The metabolism of living systems involves many enzymes that play key roles as catalysts and are essential to biological function. Searching ligands with the ability to modulate enzyme activities is central to diagnosis and therapeutics. Peptides represent a promising class of potential enzyme modulators due to the large chemical diversity, and well-established methods for library synthesis.

Microarray Selection of Cooperative Peptides for Modulating Enzyme Activities.

Recently, peptide microarrays have been used to distinguish proteins, antibodies, viruses, and bacteria based on their binding to random sequence peptides. We reported on the use of peptide arrays to identify enzyme modulators that involve screening an array of 10,000 defined and addressable peptides on a microarray. Primary peptides were first selected to inhibit the enzyme at low μM concentrations.

Chemical shift assignments of Ribosomal protein S1 from Mycobacterium tuberculosis.

RpsA, also known as ribosomal protein S1, is an essential protein required for translation initiation of mRNAs when their Shine-Dalgarno sequence is degenerated (Sorensen et al. 1998). In addition, RpsA of Mycobacterium tuberculosis (M.

Self-assembled Nucleic Acid Nanostructures for Cancer Theranostic Medicines.

Theranostic medicine has become more promising in cancer treatment, where the cancer diagnosis and chemotherapy are combined for early diagnosis and precise treatment with improved efficacy and reduced side effects. Nanotechnology has played a critical role in developing various nanomaterials with engendered smart functions and targeted delivery. The rapid development of structural DNA nanotechnology has enabled the design and fabrication of complex nanostructures with prescribed 1D, 2D and 3D patterns in vitro and in vivo.

Spatial Organization of Enzyme Cascade on a DNA Origami Nanostructure.

Self-assembled DNA nanostructures hold great promise to organize multi-enzyme systems with the precise control of the geometric arrangements. Enzymes modified with single-stranded DNA anchors are assembled onto the DNA origami tiles by hybridizing with the corresponding complementary strands displayed on the surface of the DNA nanostructures. Here, we describe a protocol of assembling a two-enzyme cascade on a discrete, rectangular DNA origami tile, where the distance between enzymes is precisely controlled for investigating the distance-dependent cascade activities.

Assembly of multienzyme complexes on DNA nanostructures.

In nature, the catalytic efficiency of multienzyme complexes highly depends on their spatial organization. The positions and orientations of the composite enzymes are often precisely controlled to facilitate substrate transport between them. Self-assembled DNA nanostructures hold great promise for organizing biomolecules at the nanoscale.

(1)H, (15)N, (13)C resonance assignments for pyrazinoic acid binding domain of ribosomal protein S1 from Mycobacterium tuberculosis.

Ribosomal protein S1 of Mycobacterium tuberculosis (MtRpsA) binds to ribosome and mRNA, and plays significant role in the regulation of translation initiation, conventional protein synthesis and transfer-messenger RNA (tmRNA) mediated trans-translation. It has been identified as the target of pyrazinoic acid (POA), a bactericidal moiety from hydrolysis of pyrazinamide, which is a mainstay of combination therapy for tuberculosis. POA prevented the interactions between the C-terminal S1 domain of MtRpsA (residues 280-368, MtRpsA(CTD)_S1) and tmRNA; so that POA can inhibit the trans-translation, which is a key component of multiple quality control pathways in bacteria.

A Hidden Transhydrogen Activity of a FMN-Bound Diaphorase under Anaerobic Conditions.

Background: Redox cofactors of NADH/NADPH participate in many cellular metabolic pathways for facilitating the electron transfer from one molecule to another in redox reactions. Transhydrogenase plays an important role in linking catabolism and anabolism, regulating the ratio of NADH/NADPH in cells. The cytoplasmic transhydrogenases could be useful to engineer synthetic biochemical pathways for the production of high-value chemicals and biofuels.

A Three-Enzyme Pathway with an Optimised Geometric Arrangement to Facilitate Substrate Transfer.

Cascade reactions drive and regulate a variety of metabolic activities. Efficient coupling of substrate transport between enzymes is important for overall pathway activity and also controls the depletion of intermediate molecules that drive the reaction forward. Here, we assembled a three-enzyme pathway on a series of DNA nanoscaffolds to investigate the dependence of their activities on spatial arrangement.