High-Throughput Screening of Signal Peptide Library with Novel Fluorescent Probe

Nitrile hydratase (NHase) is an excellent biocatalyst for the synthesis of amide compounds and is composed of two heterologous subunits. However, the secretory expression of NHase has been difficult to achieve because of its complex expression mechanism. In this work, a novel fluorescent probe Rho-IDA-CoII was synthesized by a one-pot method. Rho-IDA-CoII could specifically label His-tagged proteins in vitro, such as for staining in-gel, Western blot, and ELISA analysis. Furthermore, Rho-IDA-CoII combined with dot blots could quantitatively detect His-tagged proteins at between 1–10 pmol and perform high-throughput screening for the NHase signal peptide library. Recombinant Bacillus subtilis WB800/phoB-HBA with the extracellular expression of NHase was screened (ca. 6500 clones). After optimization of fermentation conditions, the NHase activity in the culture supernatant reached 17.34±0.16 U/mL. This is the first time that secretory NHase has been expressed in B. subtilis successfully.     

Optimized fluorescent trimethoprim derivatives for in vivo protein labeling

The combined technologies of optical microscopy and selective probes allow for real-time analysis of protein function in living cells. Synthetic chemistry offers a means to develop specific, protein-targeted probes that exhibit greater optical and chemical functionality than the widely used fluorescent proteins. Here we describe pharmacokinetically optimized, fluorescent trimethoprim (TMP) analogues that can be used to specifically label recombinant proteins fused to E. coli dihydrofolate reductase (eDHFR) in living, wild-type mammalian cells. These improved fluorescent tags exhibited high specificity and fast labeling kinetics, and they could be detected at a high signal-to-noise ratio by using fluorescence microscopy and fluorescence-activated cell sorting (FACS). We also show that fluorescent TMP-eDHFR complexes are complements to green fluorescent protein (GFP) for two-color protein labeling experiments in cells.     

Polyamide Fluorescent Probes for Visualization of Repeated DNA Sequences in Living Cells

DNA imaging in living cells usually requires transgenic approaches that modify the genome. Synthetic pyrrole‐imidazole polyamides that bind specifically to the minor groove of double‐stranded DNA (dsDNA) represent an attractive approach for in‐cell imaging that does not necessitate changes to the genome. Nine hairpin polyamides that target mouse major satellite DNA were synthesized. Their interactions with synthetic target dsDNA fragments were studied by thermal denaturation, gel‐shift electrophoresis, circular dichroism, and fluorescence spectroscopy. The polyamides had different affinities for the target DNA, and fluorescent labeling of the polyamides affected their affinity for their targets. We validated the specificity of the probes in fixed cells and provide evidence that two of the probes detect target sequences in mouse living cell lines. This study demonstrates for the first time that synthetic compounds can be used for the visualization of the nuclear substructures formed by repeated DNA sequences in living cells.     

Approaches to Introduce Helical Structure in Cysteine-Containing Peptides with a Bimane Group

An i−i+4 or i−i+3 bimane-containing linker was introduced into a peptide known to target Estrogen Receptor alpha (ERα), in order to stabilise an α-helical geometry. These macrocycles were studied by CD and NMR to reveal the i−i+4 constrained peptide adopts a 3₁₀-helical structure in solution, and an α-helical conformation on interaction with the ERα coactivator recruitment surface in silico. An acyclic bimane-modified peptide is also helical, when it includes a tryptophan or tyrosine residue; but is significantly less helical with a phenylalanine or alanine residue, which indicates such a bimane modification influences peptide structure in a sequence dependent manner. The fluorescence intensity of the bimane appears influenced by peptide conformation, where helical peptides displayed a fluorescence increase when TFE was added to phosphate buffer, compared to a decrease for less helical peptides. This study presents the bimane as a useful modification to influence peptide structure as an acyclic peptide modification, or as a side-chain constraint to give a macrocycle.     

Brevetoxin,the Dinoflagellate Neurotoxin,Localizes to Thylakoid Membranes and Interacts with the Light‐Harvesting Complex II (LHCII) of Photosystem II

The brevetoxins are neurotoxins that are produced by the “Florida red tide” dinoflagellate Karenia brevis. They bind to and activate the voltage‐gated sodium channels in higher organisms, specifically the Na_v1.4 and Na_v1.5 channel subtypes. However, the native physiological function that the brevetoxins perform for K. brevis is unknown. By using fluorescent and photoactivatable derivatives, brevetoxin was shown to localize to the chloroplast of K. brevis where it binds to the light‐harvesting complex II (LHCII) and thioredoxin. The LHCII is essential to non‐photochemical quenching (NPQ), whereas thioredoxins are critical to the maintenance of redox homeostasis within the chloroplast and contribute to the scavenging of reactive oxygen. A culture of K. brevis producing low levels of toxin was shown to be deficient in NPQ and produced reactive oxygen species at twice the rate of the toxic culture, implicating a role in NPQ for the brevetoxins.     

A Targeted Releasable Affinity Probe (TRAP) for In Vivo Photocrosslinking

A protein TRAP : The in vivo photocrosslinking of TRAP after its intracellular targeting to a binding sequence on the bait protein stabilizes protein interactions. Because the crosslinker is releasable, simple mass spectrometry can be used to identify the protein binding sites after purification.

     

A Bimane-Based Peptide Staple for Combined Helical Induction and Fluorescent Imaging

The thiol-selective fluorescent imaging agent, dibromobimane, has been repurposed to crosslink cysteine- and homocysteine-containing peptides, with the resulting bimane linker acting as both a structural constraint and a fluorescent tag. Macrocyclisation was conducted on nine short peptides containing two cysteines and/or homocysteines, both on-resin and in buffered aqueous solution, to give macrocycles ranging in size from 16 (i,i+2) to 31 (i,i+7) atoms. The structures were defined by CD, NMR structure calculations by using Xplor-NIH, NMR secondary shift and J_HαNH analyses to reveal helical structure in the i,i+4 ( 1 , 2 ), and i,i+3 ( 5 ) constrained peptides. Cellular-uptake studies were conducted with three of the macrocycles. Subsequent confocal imaging revealed punctate fluorescence within the cytosol indicative of peptides trapped in endocytic vesicles. These studies demonstrate that dibromobimane is an effective tool for defining secondary structure within short peptides, whilst simultaneously introducing a fluorescent tag suitable for common cell-based experiments.     

Evaluation of Pseudoenantiomeric Mixed Carbonates as Efficient Fluorogenic Probes for Enantioselectivity Screening

We report mixed carbonates as enzyme substrates and demonstrate their application as fluorogenic probes for lipase and esterase enantiopreference screening. By the application of pseudoenantiomers with distinct fluorescence behaviors, it is possible to evaluate the activity and enantiopreference of hydrolytic enzymes. In order to validate our method, enantioselectivities calculated from fluorometric measurements were compared with the results obtained from larger‐scale kinetic resolution.     

A Fluorogenic AggTag Method Based on Halo- and SNAP-Tags to Simultaneously Detect Aggregation of Two Proteins in Live Cells

Protein aggregation involves the assembly of partially misfolded proteins into oligomeric and higher-order structures that have been associated with several neurodegenerative diseases. However, numerous questions relating to protein aggregation remain unanswered due to the lack of available tools for visualization of these species in living cells. We recently developed a fluorogenic method named aggregation tag (AggTag), and presented the AggTag probe P1 , based on a Halo-tag ligand, to report on the aggregation of a protein of interest (POI) in live cells. However, the Halo-tag-based AggTag method only detects the aggregation of one specific POI at a time. In this study, we have expanded the AggTag method by using SNAP-tag technology to enable fluorogenic and biorthogonal detection of the aggregation of two different POIs simultaneously in live cells. A new AggTag probe— P2 , based on a SNAP-tag ligand bearing a green solvatochromic fluorophore—was synthesized for this purpose. Using confocal imaging and chemical crosslinking experiments, we confirmed that P2 can also report both on soluble oligomers and on insoluble aggregates of a POI fused with SNAP-tag in live cells. Ultimately, we showed that the orthogonal fluorescence of P1 and P2 allows for simultaneous visualization of two different pathogenic protein aggregates in the same cell.     

Molecular Design of an Environmentally Sensitive Fluorescent Nucleoside, 3‐Deaza‐2′‐Deoxyadenosine Derivative: Distinguishing Thymine by Probing the DNA Minor Groove

An environmentally sensitive fluorescent nucleoside containing a 3‐deazaadenine skeleton has been developed, and its photophysical properties were investigated. Newly developed C3‐naphthylethynylated 3‐deaza‐2′‐deoxyadenosine (^3nzA, 1 ) exhibited dual fluorescence emission from an intramolecular charge‐transfer state and a locally excited state, depending upon molecular coplanarity. DNA probes containing 1 clearly discriminated a perfectly matched thymine base on the complementary strand by a distinct change in emission wavelength.     

Patchwork Protein Chemistry: A Practitioner's Treatise on the Advances in Synthetic Peptide Stitchery

With the study of peptides and proteins at the heart of many scientific endeavors, the omics era heralded a multitude of opportunities for chemists and biologists alike. Across the interface with life sciences, peptide chemistry plays an indispensable role, and progress made over the past decades now allows proteins to be treated as molecular patchworks stitched together through synthetic tailoring. The continuous elaboration of sophisticated strategies notwithstanding, Merrifield's solid‐phase methodology remains a cornerstone of chemical protein design. Although the non‐practitioner might misjudge peptide synthesis as trivial, routine, or dull given its long history, we comment here on its many advances, obstacles, and prospects from a practitioner's point of view. While sharing our perspectives through thematic highlights across the literature, this treatise provides an interpretive overview as a guide to novices, and a recap for specialists.     

Acid-Denatured Green Fluorescent Protein (GFP) as Model Substrate to Study the Chaperone Activity of Protein Disulfide Isomerase

Green fluorescent protein (GFP) has been widely used in several molecular and cellular biology applications, since it is remarkably stable in vitro and in vivo. Interestingly, native GFP is resistant to the most common chemical denaturants; however, a low fluorescence signal has been observed after acid-induced denaturation. Furthermore, this acid-denatured GFP has been used as substrate in studies of the folding activity of some bacterial chaperones and other chaperone-like molecules. Protein disulfide isomerase enzymes, a family of eukaryotic oxidoreductases that catalyze the oxidation and isomerization of disulfide bonds in nascent polypeptides, play a key role in protein folding and it could display chaperone activity. However, contrasting results have been reported using different proteins as model substrates. Here, we report the further application of GFP as a model substrate to study the chaperone activity of protein disulfide isomerase (PDI) enzymes. Since refolding of acid-denatured GFP can be easily and directly monitored, a simple micro-assay was used to study the effect of the molecular participants in protein refolding assisted by PDI. Additionally, the effect of a well-known inhibitor of PDI chaperone activity was also analyzed. Because of the diversity their functional activities, PDI enzymes are potentially interesting drug targets. Since PDI may be implicated in the protection of cells against ER stress, including cancer cells, inhibitors of PDI might be able to enhance the efficacy of cancer chemotherapy; furthermore, it has been demonstrated that blocking the reductive cleavage of disulfide bonds of proteins associated with the cell surface markedly reduces the infectivity of the human immunodeficiency virus. Although several high-throughput screening (HTS) assays to test PDI reductase activity have been described, we report here a novel and simple micro-assay to test the chaperone activity of PDI enzymes, which is amenable for HTS of PDI inhibitors.     

Improving the Solubility of Artificial Ligands of Streptavidin to Enable More Practical Reversible Switching of Protein Localization in Cells

Chemical inducers that can control target‐protein localization in living cells are powerful tools to investigate dynamic biological systems. We recently reported the retention using selective hook or “RUSH” system for reversible localization change of proteins of interest by addition/washout of small‐molecule artificial ligands of streptavidin (ALiS). However, the utility of previously developed ALiS was restricted by limited solubility in water. Here, we overcame this problem by X‐ray crystal structure‐guided design of a more soluble ALiS derivative (ALiS‐3), which retains sufficient streptavidin‐binding affinity for use in the RUSH system. The ALiS‐3–streptavidin interaction was characterized in detail. ALiS‐3 is a convenient and effective tool for dynamic control of α‐mannosidase II localization between ER and Golgi in living cells.     

Integrin‐Targeting Fluorescent Proteins: Exploration of RGD Insertion Sites

The potential of the fluorescent protein scaffold to control peptide sequence functionality is illustrated by an exploration of fluorescent proteins as novel probes for targeting integrins. A library of fluorescent mCitrine proteins with RGD motifs incorporated at several positions in loops within the protein main chain was generated and characterized. Amino acid mutations to RGD as well as RGD insertions were evaluated: both led to constructs with typical mCitrine fluorescent properties. Screening experiments against four human integrin receptors revealed two strong‐binding constructs and two selective integrin binders. The effect of the site of RGD incorporation illustrates the importance of the protein scaffold on RGD sequence functionality, leading to fluorescent protein constructs with the potential for selective integrin targeting.     

An ACP structural switch: conformational differences between the apo and holo forms of the actinorhodin polyketide synthase acyl carrier protein

The actinorhodin (act) synthase acyl carrier protein (ACP) from Streptomyces coelicolor plays a central role in polyketide biosynthesis. Polyketide intermediates are bound to the free sulfhydryl group of a phosphopantetheine arm that is covalently linked to a conserved serine residue in the holo form of the ACP. The solution NMR structures of both the apo and holo forms of the ACP are reported, which represents the first high resolution comparison of these two forms of an ACP. Ensembles of twenty apo and holo structures were calculated and yielded atomic root mean square deviations of well-ordered backbone atoms to the average coordinates of 0.37 and 0.42 A, respectively. Three restraints defining the protein to the phosphopantetheine interface were identified. Comparison of the apo and holo forms revealed previously undetected conformational changes. Helix III moved towards helix II (contraction of the ACP), and Leu43 on helix II subtly switched from being solvent exposed to forming intramolecular interactions with the newly added phosphopantetheine side chain. Tryptophan fluorescence and S. coelicolor fatty acid synthase (FAS) holo-synthase (ACPS) assays indicated that apo-ACP has a twofold higher affinity (K(d) of 1.1 muM) than holo-ACP (K(d) of 2.1 muM) for ACPS. Site-directed mutagenesis of Leu43 and Asp62 revealed that both mutations affect binding, but have differential affects on modification by ACPS. Leu43 mutations in particular strongly modulate binding affinity for ACPS. Comparison of apo- and holo-ACP structures with known models of the Bacillus subtilis FAS ACP-holo-acyl carrier protein synthase (ACPS) complex suggests that conformational modulation of helix II and III between apo- and holo-ACP could play a role in dissociation of the ACP-ACPS complex.