Dual Illumination Enhances Transformation of an Engineered Green-to-Red Photoconvertible Fluorescent Protein

The molecular mechanisms for the photoconversion of fluorescent proteins remain elusive owing to the challenges of monitoring chromophore structural dynamics during the light-induced processes. We implemented time-resolved electronic and stimulated Raman spectroscopies to reveal two hidden species of an engineered ancestral GFP-like protein LEA, involving semi-trapped protonated and trapped deprotonated chromophores en route to photoconversion in pH 7.9 buffer. A new dual-illumination approach was examined, using 400 and 505 nm light simultaneously to achieve faster conversion and higher color contrast. Substitution of UV irradiation with visible light benefits bioimaging, while the spectral benchmark of a trapped chromophore with characteristic ring twisting and bridge-H bending motions enables rational design of functional proteins. With the improved H-bonding network and structural motions, the photoexcited chromophore could increase the photoswitching-aided photoconversion while reducing trapped species.     

Visualizing Soluble Protein Mutants by Using Monomeric Red Fluorescent Protein as a Reporter for Directed Evolution

Directed evolution-based protein engineering usually generates large library contained insoluble mutants because of structural disturbance by mutation. To reduce the workload and costs, it is crucial to identify and eliminate those insoluble variants prior to dedicated analysis. Here, we demonstrate a method to visualize soluble protein mutants by using monomeric red fluorescent protein (mRFP) as a fusion tag. A plasmid was devised to express nicotinic acid mononucleotide adenylyltransferase (NadD) fused with a GGGS-linked mRFP tag at the C-terminus. The plasmid was subjected to site saturation mutagenesis within the nadD gene, used to transform Escherichia coli DH10B competent cells, leading to colonies with different red intensities. It was found that the fluorescence intensity of the cell culture correlated positively with the content of NadD-mRFP mutant in the supernatant. Mutation at position 132 led to a library of which most colonies lost the red phenotype, indicating that the position had a key role for proper protein folding. Similarly, mRFP enabled identification of soluble mutants of other enzymes including 1-deoxy-D-xylulose-5-phosphate reductoisomerase and phosphite dehydrogenase. These data suggested that mRFP can serve as a fusion reporter for visualizing soluble protein mutants to facilitate more efficient library screening in directed evolution.     

An Atypical Naturally Split Intein Engineered for Highly Efficient Protein Labeling

Protein trans‐splicing catalyzed by split inteins is a powerful technique for assembling a polypeptide backbone from two separate parts. However, split inteins with robust efficiencies and short fragments suitable for peptide synthesis are rare and have mostly been artificially created. The novel split intein AceL‐TerL was identified from metagenomic data and characterized. It represents the first naturally occurring, atypically split intein. The N‐terminal fragment of only 25 amino acids is the shortest natural intein fragment to date and was easily amenable to chemical synthesis with a fluorescent label. Optimal protein trans‐splicing activity was observed at low temperatures. Further improved mutants were selected by directed protein evolution. The engineered intein variants with up to 50‐fold increased rates showed unprecedented efficiency in chemically labeling of a diverse set of proteins. These inteins should prove valuable tools for protein semi‐synthesis and other intein‐related biotechnological applications.     

绿色荧光蛋白

绿色荧光蛋白是46多年前从多管水母体内发现的,它可以在蓝光或紫外光激发下发射绿光.由于它稳定的结构和光物理性质,又易于在细胞内表达,近些年作为标记物已经被广泛地应用于生命科学领域.本文简要介绍了水母发光蛋白与绿色荧光蛋白的关系、绿色荧光蛋白的结构、发色团的形成、发光机制、变异体以及它的特点和应用.     

Dual Illumination Enhances Transformation of an Engineered Green‐to‐Red Photoconvertible Fluorescent Protein

The molecular mechanisms for the photoconversion of fluorescent proteins remain elusive owing to the challenges of monitoring chromophore structural dynamics during the light‐induced processes. We implemented time‐resolved electronic and stimulated Raman spectroscopies to reveal two hidden species of an engineered ancestral GFP‐like protein LEA, involving semi‐trapped protonated and trapped deprotonated chromophores en route to photoconversion in pH 7.9 buffer. A new dual‐illumination approach was examined, using 400 and 505 nm light simultaneously to achieve faster conversion and higher color contrast. Substitution of UV irradiation with visible light benefits bioimaging, while the spectral benchmark of a trapped chromophore with characteristic ring twisting and bridge‐H bending motions enables rational design of functional proteins. With the improved H‐bonding network and structural motions, the photoexcited chromophore could increase the photoswitching‐aided photoconversion while reducing trapped species.     

An Engineered OmpG Nanopore with Displayed Peptide Motifs for Single-Molecule Multiplex Protein Detection

Molecular detection via nanopore, achieved by monitoring changes in ionic current arising from analyte interaction with the sensor pore, is a promising technology for multiplex sensing development. Outer Membrane Protein G (OmpG), a monomeric porin possessing seven functionalizable loops, has been reported as an effective sensing platform for selective protein detection. Using flow cytometry to screen unfavorable constructs, we identified two OmpG nanopores with unique peptide motifs displayed in either loop 3 or 6, which also exhibited distinct analyte signals in single-channel current recordings. We exploited these motif-displaying loops concurrently to facilitate single-molecule multiplex protein detection in a mixture. We additionally report a strategy to increase sensor sensitivity via avidity motif display. These sensing schemes may be expanded to more sophisticated designs utilizing additional loops to increase multiplicity and sensitivity.     

Engineered Hsp Protein Nanocages for siRNA Delivery

The efficient delivery of small interfering RNA (siRNA) to tumor cells still remains a great challenge. Of the various nanocarriers, protein nanocages have attracted extensive interest due to their unique structure and suitable characteristics derived from their proteinaceous nature. However, most reported protein nanocages that are developed are based on virus capsid proteins, which may raise safety concerns, including those related to gene mutation and carcinogenesis. The development of nonviral protein‐based systems for siRNA delivery is greatly needed. In this study, a novel siRNA delivery system based on heat shock protein (Hsp) nanocages is developed by a genetic engineering method. The delivery system could condense siRNA into stable complexes and protect the condensed siRNA from degradation. A cellular uptake analysis shows that siRNA is introduced into tumor cells mediated by Hsp‐R9 nanocages. Green fluorescent protein (GFP) expression in HeLa‐EGFP cells is significantly downregulated by Hsp‐R9/siRNA complexes. The results indicate that Hsp nanocages may be a good platform for siRNA delivery into tumor cells.     

蛋白质标记荧光探针的研究及其进展

蛋白质标记荧光探针在生物分析及蛋白质组学中的应用日益广泛,被用于在分子水平上分析和识别蛋白质,检测蛋白质复杂的构象变化及各项生理活动过程如蛋白质之间的相互作用等.本文评述了近年来该类探针的研究及进展,展望了其应用前景,引用文献63篇.     

Supramolecular Assembly of a Molecularly Engineered Protein and Polymer

Programmable assembly of biomolecules is a fast growing research area that aims to emulate nature's elegance in creating numerous hierarchical self-assembled structures, which are responsible for unimaginably difficult biological functions. Protein assembly is a particularly challenging task, owing to their structural diversity, conformational heterogeneity, and high molecular weight. This article reveals the ability of a supramolecular structure-directing unit (SSDU) to regulate the entropically favourable supramolecular assembly of a covalently conjugated protein (bovine serum albumin (BSA)) to produce well-defined protein-decorated micelles with remarkably high thermal stability, suppression of the thermal denaturation of the protein, and retention of enzymatic activity. Furthermore, a SSDU-appended thermo-responsive poly(N-isopropylacrylamide) (PNIPAM) co-assembles with the SSDU–BSA conjugate because, in both cases, assembly was primarily driven by specific molecular recognition between the SSDUs. However, the resulting supramolecular protein–polymer conjugate exhibits distinctly different polymersome structure to that of the micellar particle produced by the protein-SSDU conjugate. In this case, the enzymatic activity can be significantly suppressed above the lower critical solution temperature of supramolecularly conjugated PNIPAM, possibly due to collapse of the de-solvated polymer chains on the protein surface.     

Sensing Protein Surfaces with Targeted Fluorescent Receptors

A methodology for creating fluorescent molecular sensors that respond to changes that occur on the surfaces of specific proteins is presented. This approach, which relies on binding cooperatively between a specific His‐tag binder and a nonspecific protein‐surface receptor, enabled the development of a sensor that can track changes on the surface of a His‐tag‐labeled calmodulin (His‐CaM) upon interacting with metal ions, small molecules, and protein binding partners. The way this approach was used to detect dephosphorylation of an unlabeled calmodulin‐dependent protein kinase II (CaMKII), and the binding of Bax BH3 to His‐tagged B‐cell lymphoma 2 (Bcl‐2) protein is also presented.     

Time-Resolved Emission Spectra of Green Fluorescent Protein

The time-resolved emission spectra of wild-type green fluorescent protein (wtGFP) and the T203V GFP mutant have been recorded with picosecond time resolution, allowing the separate characterization of the two spectral components associated with the neutral and anionic forms of the GFP chromophore. Significantly, neither component shifts as a function of time. It is suggested that the absence of spectral shift is a result of highly restricted movement of the protein residues in the vicinity of the chromophore. The shapes of the separated spectra are discussed and their relative ratio analyzed in a steady-state analysis.     

Directed Molecular Stacking for Engineered Fluorescent Three-Dimensional Reduced Graphene Oxide and Coronene Frameworks

Three-dimensional fluorescent graphene frameworks with controlled porous morphologies are of significant importance for practical applications reliant on controlled structural and electronic properties, such as organic electronics and photochemistry. Here we report a synthetically accessible approach concerning directed aromatic stacking interactions to give rise to new fluorogenic 3D frameworks with tuneable porosities achieved through molecular variations. The binding interactions between the graphene-like domains present in the in situ-formed reduced graphene oxide (rGO) with functional porphyrin molecules lead to new hybrids via an unprecedented solvothermal reaction. Functional free-base porphyrins featuring perfluorinated aryl groups or hexyl chains at their meso- and β-positions were employed in turn to act as directing entities for the assembly of new graphene-based and foam-like frameworks and of their corresponding coronene-based hybrids. Investigations in the dispersed phase and in thin-film by XPS, SEM and FLIM shed light onto the nature of the aromatic stacking within functional rGO frameworks (denoted rGOFs) which was then modelled semi-empirically and by DFT calculations. The pore sizes of the new emerging reduced graphene oxide hybrids are tuneable at the molecular level and mediated by the bonding forces with the functional porphyrins acting as the “molecular glue”. Single crystal X-ray crystallography described the stacking of a perfluorinated porphyrin with coronene, which can be employed as a molecular model for understanding the local aromatic stacking order and charge transfer interactions within these rGOFs for the first time. This opens up a new route to controllable 3D framework morphologies and pore size from the Ångstrom to the micrometre scale. Theoretical modelling showed that the porosity of these materials is mainly due to the controlled inter-planar distance between the rGO, coronene or graphene sheets. The host-guest chemistry involves the porphyrins acting as guests held through π-π stacking, as demonstrated by XPS. The objective of this study is also to shed light into the fundamental localised electronic and energy transfer properties in these new molecularly engineered porous and fluorogenic architectures, aiming in turn to understand how functional porphyrins may exert stacking control over the notoriously disordered local structure present in porous reduced graphene oxide fragments. By tuning the porosity and the distance between the graphene sheets using aromatic stacking with porphyrins, it is also possible to tune the electronic structure of the final nanohybrid material, as indicated by FLIM experiments on thin films. Such nanohybrids with highly controlled pores dimensions and morphologies open the way to new design and assembly of storage devices and applications incorporating π-conjugated molecules and materials and their π-stacks may be relevant towards selective separation membranes, water purification and biosensing applications.     

蛋白质分子荧光探针研究及其应用新进展

人体中多达10万种以上的蛋白质结构,功能千差万别,形成了生命的多样性和复杂性。在分子水平上分析和识别蛋白质对生命科学研究具有重要的理论和实践意义。本文综述了各种蛋白质分子荧光探针在蛋白质分析方面的应用,并展望了此类荧光探针的发展趋势和应用前景。引用文献60篇。     

Flexible Alkylene Bridges as a Tool To Engineer Crystal Distyrylbenzene Structures Enabling Highly Fluorescent Monomeric Emission

To design ultrabright fluorescent solid dyes, a crystal engineering strategy that enables monomeric emission by blocking intermolecular electronic interactions is required. We introduced propylene moieties to distyrylbenzene (DSB) as bridges between the phenyl rings either side of its C=C bonds. The bridged DSB derivatives formed compact crystals that emit colors similar to those of the same molecules in dilute solution, with high quantum yields. The introduction of flexible seven-membered rings to the DSB core produced moderate distortion and steric hindrance in the DSB π-plane. However, owing to this strategy, it was possible to control the molecular arrangement with almost no decrease in the crystal density, and intermolecular electronic interactions were suppressed. The bridged DSB crystal structure differs from other DSB derivative structures; thus, bridging affords access to novel crystalline systems. This design strategy has important implications in many fields and is more effective than the conventional photofunctional molecular crystal design strategies.     

Highly Fluorescent Green Fluorescent Protein Chromophore Analogues Made by Decorating the Imidazolone Ring

The synthesis and photophysical behavior of an unexplored family of green fluorescent protein (GFP)‐like chromophore analogues is reported. The compound (Z)‐4‐(4‐hydroxybenzylidene)‐1‐propyl‐2‐(propylamino)‐1H‐imidazol‐5(4 H)‐one (p‐HBDNI, 2 a ) exhibits significantly enhanced fluorescence properties relative to the parent compound (Z)‐5‐(4‐hydroxybenzylidene)‐2,3‐dimethyl‐3,5‐dihydro‐4H‐imidazol‐4‐one (p‐HBDI, 1 ). p‐HBDNI was considered as a model system and the photophysical properties of other novel 2‐amino‐3,5‐dihydro‐4H‐imidazol‐4‐one derivatives were evaluated. Time‐dependent DFT calculations were carried out to rationalize the results. The analogue AIDNI ( 2 c ), in which the 4‐hydroxybenzyl group of p‐HBDNI was replaced by an azaindole group, showed improved photophysical properties and potential for cell staining. The uptake and intracellular distribution of 2 c in living cells was investigated by confocal microscopy imaging.     

Engineered Upconversion Nanoparticles for Resolving Protein Interactions inside Living Cells

Upconversion nanoparticles (UCNPs) convert near‐infrared into visible light at much lower excitation densities than those used in classic two‐photon absorption microscopy. Here, we engineered <50 nm UCNPs for application as efficient lanthanide resonance energy transfer (LRET) donors inside living cells. By optimizing the dopant concentrations and the core–shell structure for higher excitation densities, we observed enhanced UCNP emission as well as strongly increased sensitized acceptor fluorescence. For the application of these UCNPs in complex biological environments, we developed a biocompatible surface coating functionalized with a nanobody recognizing green fluorescent protein (GFP). Thus, rapid and specific targeting to GFP‐tagged fusion proteins in the mitochondrial outer membrane and detection of protein interactions by LRET in living cells was achieved.     

Metal-Induced Fluorescence Quenching of Photoconvertible Fluorescent Protein DendFP

Sensitive and accurate detection of specific metal ions is important for sensor development and can advance analytical science and support environmental and human medical examinations. Fluorescent proteins (FPs) can be quenched by specific metal ions and spectroscopically show a unique fluorescence-quenching sensitivity, suggesting their potential application as FP-based metal biosensors. Since the characteristics of the fluorescence quenching are difficult to predict, spectroscopic analysis of new FPs is important for the development of FP-based biosensors. Here we reported the spectroscopic and structural analysis of metal-induced fluorescence quenching of the photoconvertible fluorescent protein DendFP. The spectroscopic analysis showed that Fe²⁺, Fe³⁺, and Cu²⁺ significantly reduced the fluorescence emission of DendFP. The metal titration experiments showed that the dissociation constants (K_d) of Fe²⁺, Fe³⁺, and Cu²⁺ for DendFP were 24.59, 41.66, and 137.18 μM, respectively. The tetrameric interface of DendFP, which the metal ions cannot bind to, was analyzed. Structural comparison of the metal-binding sites of DendFP with those of iq-mEmerald and Dronpa suggested that quenchable DendFP has a unique metal-binding site on the β-barrel that does not utilize the histidine pair for metal binding.     

Metal Affinity-Based Purification of a Red Fluorescent Protein

A red fluorescent protein, DsRed, which emits fluorescence in the red region of the spectrum has become a popular alternative to green fluorescent protein as a label in biochemical and bioanalytical applications. In this study, we have developed a simple purification method for DsRed variants utilizing their inherent copper binding property. A purification procedure was developed and optimized using immobilized copper ions yielding a single strong band corresponding to purified DsRed proteins on the SDS-PAGE gel. A purification efficiency of higher than 95% was achieved. A spectral analysis and copper binding study was performed to verify activity of the purified proteins. The development of this method allows DsRed to play a dual role as a fluorescent reporter protein and as a purification affinity tag for a target protein. This simpler approach of purification should expand the utility of DsRed.