Allosteric Probe Research Articles

Enzyme-accelerated catalytic DNA circuits enable rapid and one-pot detection of bacterial pathogens

Catalytic DNA circuits, serving as signal amplification strategies, can enable simple and accurate detection of pathogenic bacteria in complex matrices but suffer from low reaction rates and depths. Herein, we design an enzyme-accelerated catalytic hairpin assembly (EACHA) in which duplex DNA products are converted into hairpin reactants to continue participating in the next circuit reaction with the assistance of RNase H. Profiting from the high recyclability of the reactants, EACHA exhibits an approximately 37.6-fold enhancement in the rate constant and a two-order-of-magnitude improvement in sensitivity compared to conventional catalytic hairpin assembly (CHA). By integrating an allosteric probe with EACHA, a one-pot method is developed for rapid and direct detection of S. enterica Enteritidis (S. Enteritidis). This method is capable of detecting 15 CFU mL−1 of S. Enteritidis within 20 min, which is superior to that of real-time PCR. By testing 60 milk samples, we demonstrate this method's high accuracy in discriminating contaminated samples, with an area under the curve (AUC) of 0.997. Moreover, this method can be employed to accurately diagnose early-stage infected mice, with an AUC of 1.00 for feces samples and 0.986 for serum samples. Therefore, this study offers a simple and feasible method for identifying pathogens in complex matrices.

Sensitive Detection of Escherichia coli O157:H7 Using Allosteric Probe and Hairpin Switches-Based Isothermal Transcription Amplification.

Pathogens pose a serious threat to public and population health, leading to serious outbreak and spread of diseases irrespective of the region. The capability to directly, sensitively, and specifically detect viable pathogens in low numbers in food and clinical samples is very desirable but remains a challenge. In this work, we present a novel assay of a combination of an aptamer-based allosteric probe and hairpin switch-controlled T7 RNA polymerase-based isothermal transcription amplification, which enables rapid, ultrasensitive, label-free detection of direct pathogens. It can detect Escherichia coli as low as 73.2 CFU/mL. Moreover, with the usage of the proposed assay, sensitive quantification of E. coliO157:H7 in milk samples has been achieved, showing significant potential as a simple and sensitive tool to quantify pathogens in milk and other foods.

Labeling of CC Chemokine Receptor 2 with a Versatile Intracellular Allosteric Probe.

Interest in affinity-based probes (AfBPs) as novel tools to interrogate G protein-coupled receptors (GPCRs) has gained traction in recent years. AfBPs represent an interesting and more versatile alternative to antibodies. In the present study, we report the development and validation of AfBPs that target the intracellular allosteric pocket of CCR2, a GPCR of interest for the development of therapies targeting autoimmune and inflammatory diseases and also cancer. Owing to the two-step labeling process of these CCR2 AfBPs through the incorporation of a click handle, we were successful in applying our most efficient probe in a variety of in vitro experiments and making use of multiple different detection techniques, such as SDS-PAGE and LC/MS-based proteomics. Collectively, this novel probe shows high selectivity, versatility, and applicability. Hence, this is a valuable alternative for CCR2-targeting antibodies and other traditional tool compounds and could aid in target validation and engagement in drug discovery.

Allosteric Probe-Based Colorimetric Assay for Direct Identification and Sensitive Analysis of Methicillin Resistance of Staphylococcus aureus.

The accurate and rapid detection of methicillin-resistance of Staphylococcus aureus (SA) holds significant clinical importance. However, the methicillin-resistance detection strategies commonly require complicated cell lysis and gene extraction. Herein, we devised a novel colorimetric approach for the sensitive and accurate identification of methicillin-resistance of SA by combining allosteric probe-based target recognition with self-primer elongation-based target recycling. The PBP2a aptamer in the allosteric probe successfully identified the target MRSA, leading to the initiation of self-primer elongation based-cascade signal amplification. The peroxidase-like hemin/G-quadruplex undergo an isothermal autonomous process that effectively catalyzes the oxidation of ABTS2- and produces a distinct blue color, enabling the visual identification of MRSA at low concentrations. The method offers a shorter duration for bacteria cultivation compared to traditional susceptibility testing methods, as well as simplified manual procedures for gene analysis. The overall amplification time for this test is 60 min, and it has a detection limit of 3 CFU/ml. In addition, the approach has exceptional selectivity and reproducibility, demonstrating commendable performance when tested with real samples. Due to its advantages, this colorimetric assay exhibits considerable potential for integration into a sensor kit, thereby offering a viable and convenient alternative for the prompt and on-site detection of MRSA in patients with skin and soft tissue infections.

Orthosteric ligand selectivity and allosteric probe dependence at Hydroxycarboxylic acid receptor HCAR2

Hydroxycarboxylic acid receptor 2 (HCAR2), a member of Class A G-protein-coupled receptor (GPCR) family, plays a pivotal role in anti-lipolytic and anti-inflammatory effects, establishing it as a significant therapeutic target for treating dyslipidemia and inflammatory diseases. However, the mechanism underlying the signaling of HCAR2 induced by various types of ligands remains elusive. In this study, we elucidate the cryo-electron microscopy (cryo-EM) structure of Gi-coupled HCAR2 in complex with a selective agonist, MK-6892, resolved to a resolution of 2.60 Å. Our structural analysis reveals that MK-6892 occupies not only the orthosteric binding pocket (OBP) but also an extended binding pocket (EBP) within HCAR2. Pharmacological assays conducted in this study demonstrate that the OBP is a critical determinant for ligand selectivity among the HCARs subfamily. Moreover, we investigate the pharmacological properties of the allosteric modulator compound 9n, revealing its probe-dependent behavior on HCAR2 in response to varying orthosteric agonists. Collectively, our findings provide invaluable structural insights that contribute to a deeper understanding of the regulatory mechanisms governing HCAR2 signaling transduction mediated by both orthosteric and allosteric ligands.

Fluorimetric monitoring of vancomycin using an allosteric probe-initiated sensing platform

Vancomycin is the first-line drug for infections of methicillin-resistant Staphylococcus aureus (MRSA) and multi-drug-resistant bacteria. The effective therapeutic concentration range of vancomycin is narrow, so it's essential to implement vancomycin therapeutic drug monitoring. However, conventional detection methods have disadvantages of expensive equipment, complicated operation, or poor reproducibility. Herein, a fluorescent sensing platform initiated by an allosteric probe was constructed for simple and sensitive monitoring of vancomycin at a low cost. The key point of this platform is the well-designed allosteric probe, which comprises an aptamer and a trigger sequence. When vancomycin exists, the combination of vancomycin and the aptamer will lead to a conformational change of the allosteric probe, thus exposing the trigger sequence. The trigger can react with the molecular beacon (MB) to generate fluorescent signals. In addition, the allosteric probe combined with hybridization chain reaction (HCR) was applied to develop an amplified platform, the linear range is from 0.5 μg mL−1 to 50 μg mL−1 with the limit of detection (LOD) of 0.26 μg mL−1. Most importantly, this allosteric probe-initiated sensing platform shows good detection ability in human serum samples, and it also indicates great correlation and accuracy compared with HPLC. The present simple and sensitive allosteric probe-initiated platform has the potential to support the therapeutic drug monitoring of vancomycin, which is of great significance to promote the rational use of antibiotics in clinics.

Allosteric probe-triggered isothermal amplification to activate CRISPR/Cas12a for sensitive electrochemiluminescence detection of Salmonella

We report an electrochemiluminescence (ECL) sensor for Salmonella detection based on allosteric probe as a bio-recognition element and CRISPR/Cas12a as a signal amplification strategy. In the presence of Salmonella, the structure switching occurs on allosteric probes, resulting in their hybridization with primers to trigger isothermal amplification. Salmonella is then released to initiate the next reaction cycle accompanying by generating a large amount of dsDNA, which are subsequently recognized by CRISPR-gRNA for activating the trans-cleavage activity of Cas12a. Furthermore, the activated Cas12a can indiscriminately cut the ssDNA which is bound to the electrode, enabling the release of the ECL emitter porphyrinic Zr metal − organic framework (MOF, PCN-224) and exhibiting a decreased ECL signal accordingly. The linear range is 50 CFU·mL−1–5 × 106 CFU·mL−1 and the detection limit is calculated to be 37 CFU·mL−1. This method sensitively detects Salmonella in different types of real samples, indicating it is a promising strategy for Salmonella detection

Allosteric probe initiated triple signal recycles for sensitive analysis of adenosine triphosphate (ATP)

Adenosine triphosphate (ATP) is closely associated with a variety of pathophysiological process, providing energy for cell activities. However, it remains a huge challenge to develop a simple and sensitive ATP detection method. Herein, we describe an ultrasensitive approach for ATP detection by using an elegantly designed allosteric probe to bind with targets and to induce DNAzyme assisted triple signal recycles. To establish the approach, the allosteric probe is designed with three functional parts to bind with target ATP, to induce signal recycles and to assist chain extension. After recognition of ATP by allosteric probe, the triple signal recycles are initiated, including (i) released ATP-allosteric probe complex unfolds H1 probe, constituting the first signal recycle; (ii) DNAzyme based cleavage induces the second signal recycle; and (iii) chain extension induced release of ATP is the third signal recycle. Through a series of experiments, the approach exhibits a favorable ATP detection performance and shows a high anti-interference ability, indicating a potential application value in early diagnosis of diseases.

On-bead DNA synthesis triggered by allosteric probe for detection of carcinoembryonic antigen.

Sensitive quantification of protein biomarkers is highly desired for clinical diagnosis and treatment. Yet, unlike DNA/RNA which can be greatly amplified by PCR/RT-PCR, the amplification and detection of trace amount of proteins remain a great challenge. Here, we combined allosteric probe (AP) with magnetic bead (MB) for assembling an on-bead DNA synthesis system (named as APMB) to amplify protein signals. The AP is designed and conjugated onto the MB, enabling the protein biomarker to be separated and enriched. Once recognizing the biomarker, the AP alters its conformation to initiate DNA synthesis on beads for primary signal amplification. During the DNA synthesis, biotin-dATPs are incorporated into the newly synthesized DNA strands. Then, the biotin-labeled DNA specifically captures streptavidin (STR)–conjugated horseradish peroxidase (HRP), which is used to catalyze a colorimetric reaction for secondary signal amplification. By using carcinoembryonic antigen (CEA) as a protein model, the APMB can quantify protein biomarkers of as low as 0.01 ng/mL. The response values measured by APMB are linearly related to the protein concentrations in the range 0.05 to 20 ng/mL. Clinical examination demonstrated good practicability of the APMB in quantifying serum protein biomarker. The on-bead DNA synthesis could be exploited to improve protein signal amplification, thus facilitating protein biomarker detection of low abundance for early diagnosis.Graphical abstract Supplementary InformationThe online version contains supplementary material available at 10.1007/s00604-022-05404-4.

Allosteric Probe Recognition Initiated Cascade Transcription Amplification for Sensitive Analysis of Exosomes.

Sensitive and accurate analysis of exosomes is important for many biological processes including as a biomarker for cerebral venous thrombosis (CVT) diagnosis and therapy. Herein, we established a sensitive and specific exosome detection approach based on target recognition initiated cascade signal amplification. In this method, an allosteric probe was designed with a hairpin structure for specific recognition of the exosome followed by signal amplification. After the cascade signal amplification process, spinach RNA sequences bind to DFHBI ((Z)-4-(3,5-difluoro-4-hydroxybenzylidene)-1,2-dimethyl-1H-imidazol-5(4H)-one) to produce enhanced fluorescence signal (approximate 2000 fold than that of inactive DFHBI). Compared with former proposed exosome detection techniques, this method exhibited a comparable detection range, but with an easy-to-design toolbox. Therefore, we believe that the proposed approach holds great potential for exosome based early diagnosis and prognosis of disease.

On-Bead DNA Synthesis Triggered by Allosteric Probe for Sensitive Detection of Protein Biomarker

On-Bead DNA Synthesis Triggered by Allosteric Probe for Sensitive Detection of Protein Biomarker

Accurate and sensitive analysis of Staphylococcus aureus through CRISPR-Cas12a based recycling signal amplification cascades for early diagnosis of skin and soft tissue infections

Early-diagnosis and treatments of skin and soft tissue infections remain a huge challenge due to the difficulties in the detection of trace amounts of bacteria. We develop here a novel method through CRISPR-Cas12a based recycling signal amplification cascades and demonstrated its feasibility of Staphylococcus aureus detection in a sensitive and accurate way. The highlights of the proposed method are calculated as: i) the designed allosteric probe is responsible for accurate identification of SA through PBP2a-specific aptamer; ii) high sensitivity from three processes, including DNA polymerase-based target SA release, Nb.BbvCI enzyme induced ssDNA generation and attached CRISPR-Cas12a. As a result, the proposed method exhibited a detection range from 106 to 102 CFU/ml. Eventually, we believe that the proposed method could be expanded for the construction of diverse sensing platforms for detecting different trace bacteria.

Four-stage signal amplification for trace ATP detection using allosteric probe-conjugated strand displacement and CRISPR/Cpf1 trans-cleavage (ASD-Cpf1)

High-performance detection of adenosine triphosphate (ATP) is of great importance due to its irreplaceable roles in various physiological processes. In this work, a four-stage signal amplification was established for ATP detection based on an allosteric probe-conjugated strand displacement amplification (SDA) integrated with CRISPR/Cpf1 system (ASD-Cpf1). An allosteric probe (AH) with a hairpin structure was designed to reduce background interference from self-extension and non-specific amplification during the SDA reaction. ATP bound with the aptamer segment at 5′-terminal of AH probe and subsequently opened the AH probe to activate the SDA reaction. The amplification products were recognized by CRISPR/Cpf1 system and triggered the ssDNase activity of Cpf1, resulting in robust cleavage of surrounding DNA FQ-reporter (fluorophore-quencher labeled short single-stranded DNA sequence). With the four-step amplification, ATP was measured with high sensitivity and low background interference. Under the optimal conditions, a linear relationship was obtained between the fluorescence response and ATP concentrations ranging from 2 pM to 10 μM with a limit of detection (LOD) as low as 1.8 pM. Successful detection of ATP in diluted human serum samples further indicated that ASD-Cpf1 system provided a potential platform for detection of small molecules.

Allosteric Probe-Initiated Wash-Free Method for Sensitive Extracellular Vesicle Detection through Dual Cycle-Assisted CRISPR-Cas12a.

Extracellular vesicles (EVs) are emerging as promising biomarkers for cancer diagnosis and therapy. Recognizing low-abundance EVs from clinical samples in an easy-to-operate way is highly desired but remains a challenge. Herein, we established an allosteric probe-initiated dual cycle amplification-assisted CRISPR-Cas12a (AID-Cas) platform for sensitive detection of EVs in a wash-free way. In AID-Cas, the allosteric probe can specifically recognize and bind with target EVs and thus initiate the following dual-cycle amplification. Subsequently, the amplified products were transcribed to generate numerous single-stranded RNAs, which could work as crRNA to trigger the trans-cleavage of CRISPR-Cas12a. Consequently, the proposed approach achieved a good linear response to extracted EVs in a concentration range from 102 to 106 particles/μL. Because of its high sensitivity, together with its wash-free convenience, the proposed strategy could have promising clinical potentials for early diagnosis of cancers.

An Allosteric-Probe for Detection of Alkaline Phosphatase Activity and Its Application in Immunoassay

A fluorescence strategy for alkaline phosphatase (ALP) assay in complicated samples with high sensitivity and strong stability is developed based on an allosteric probe (AP). This probe consists of two DNA strands, a streptavidin (SA) aptamer labeled by fluorophore and its totally complementary DNA (cDNA) with a phosphate group on the 5′ end. Upon ALP introduction, the phosphate group on the cDNA is hydrolyzed, leaving the unhydrolyzed cDNA sequence for lambda exonuclease (λ exo) digestion and releasing SA aptamer for binding to SA beads, which results in fluorescence enhancement of SA beads that can be detected by flow cytometry or microscopy. We have achieved a detection limit of 0.012 U/mL with a detection range of 0.02~0.15 U/mL in buffer and human serum. These figures of merit are better than or comparable to those of other methods. Because the fluorescence signal is localized on the beads, they can be separated to remove fluorescence background from complicated biological systems. Notably, the new strategy not only applies to ALP detection with simple design, easy operation, high sensitivity, and good compatibility in complex solution, but also can be utilized in ALP-linked immunosorbent assays for the detection of a wide range of targets.

Covalent Allosteric Probe for the Metabotropic Glutamate Receptor2: Design, Synthesis, and Pharmacological Characterization.

Covalent labeling of G protein-coupled receptors (GPCRs) by small molecules is a powerful approach to understand binding modes, mechanism of action, pharmacology, and even facilitate structure elucidation. We report the first covalent positive allosteric modulator (PAM) for a class C GPCR, the mGlu2 receptor. Three putatively covalent mGlu2 PAMs were designed and synthesized. Pharmacological characterization identified 2 to bind the receptor covalently. Computational modeling combined with receptor mutagenesis revealed T7917.29×30 as the likely position of covalent interaction. We show how this covalent ligand can be used to characterize the PAM binding mode and that it is a valuable tool compound in studying receptor function and binding kinetics. Our findings advance the understanding of the mGlu2 PAM interaction and suggest that 2 is a valuable probe for further structural and chemical biology approaches.

Prototropically Allosteric Probe for Superbly Selective DNA Analysis

Selective nucleotide recognition for biosensor evolution requires rational probe design toward the binding-pattern-susceptible readout but without serious poison in selectivity from the context sequences. In this work, we synthesized a dual-function (trihydroxyphenyl)porphyrin (POH3) to target the abasic site (AP site) in ds-DNA using the trihydroxyphenyl substituent and the tetrapyrrole macrocycle as the recognition unit (RU) and the fluorescent signal unit (SU), respectively. RU and SU are separated from each other but are prototropically allosteric. We found that an appropriate pH favors formation of the nonfluorescent quinine/pyrrole (O-NH) conformer of POH3. However, the complementary hydrogen bonding of RU in O-NH with the target cytosine opposite the AP site switches on the SU fluorescence through prototropic allostery toward the phenol/isopyrrole (OH-N) conformer, while the bases thymine, guanine, and adenine totally silence this allostery, suggesting a superb selectivity in single-nucleotide polymorphism (SNP) analysis. The role of the prototropic allostery in achieving such SNP selectivity is also evidenced using porphyrins with other hydroxyl substituent patterns. Because of the SU separation from RU, SU is not directly involved in the interaction with the AP site, and thus, the turn-on selectivity is also realized for DNA with flanking guanine, the most easily oxidized base in DNA. This tolerance to the flanking base identity has seldom been achieved in previous studies. Additionally, other DNA structures cannot bring this allostery, indicating that the combination recipe of the AP site design and the prototropically allosteric probe will find wide applications in DNA-based sensors.

A fluorescent aptasensor with product-triggered amplification by exonuclease III digestion for highly sensitive ATP detection

An improved sensitivity of an ATP detection assay was achieved by using an allosteric probe and exonuclease III digestion product-triggered signal amplification.

Mapping Cannabinoid 1 Receptor Allosteric Site(s): Critical Molecular Determinant and Signaling Profile of GAT100, a Novel, Potent, and Irreversibly Binding Probe.

One of the most abundant G-protein coupled receptors (GPCRs) in brain, the cannabinoid 1 receptor (CB1R), is a tractable therapeutic target for treating diverse psychobehavioral and somatic disorders. Adverse on-target effects associated with small-molecule CB1R orthosteric agonists and inverse agonists/antagonists have plagued their translational potential. Allosteric CB1R modulators offer a potentially safer modality through which CB1R signaling may be directed for therapeutic benefit. Rational design of candidate, druglike CB1R allosteric modulators requires greater understanding of the architecture of the CB1R allosteric endodomain(s) and the capacity of CB1R allosteric ligands to tune the receptor's information output. We have recently reported the synthesis of a focused library of rationally designed, covalent analogues of Org27569 and PSNCBAM-1, two prototypic CB1R negative allosteric modulators (NAMs). Among the novel, pharmacologically active CB1R NAMs reported, the isothiocyanate GAT100 emerged as the lead by virtue of its exceptional potency in the [(35)S]GTPγS and β-arrestin signaling assays and its ability to label CB1R as a covalent allosteric probe with significantly reduced inverse agonism in the [(35)S]GTPγS assay as compared to Org27569. We report here a comprehensive functional profiling of GAT100 across an array of important downstream cell-signaling pathways and analysis of its potential orthosteric probe-dependence and signaling bias. The results demonstrate that GAT100 is a NAM of the orthosteric CB1R agonist CP55,940 and the endocannabinoids 2-arachidonoylglycerol and anandamide for β-arrestin1 recruitment, PLCβ3 and ERK1/2 phosphorylation, cAMP accumulation, and CB1R internalization in HEK293A cells overexpressing CB1R and in Neuro2a and STHdh(Q7/Q7) cells endogenously expressing CB1R. Distinctively, GAT100 was a more potent and efficacious CB1R NAM than Org27569 and PSNCBAM-1 in all signaling assays and did not exhibit the inverse agonism associated with Org27569 and PSNCBAM-1. Computational docking studies implicate C7.38(382) as a key feature of GAT100 ligand-binding motif. These data help inform the engineering of newer-generation, druggable CB1R allosteric modulators and demonstrate the utility of GAT100 as a covalent probe for mapping structure-function correlates characteristic of the druggable CB1R allosteric space.

Allosteric enhancement by DDT of the binding of [ [formula omitted] to sodium channels

[ 3 H] Batrachotoxinin A-20-α-benzoate (BTX-B) bound to a single class of high affinity ( K d = 79 n M), low capacity ( B max = 4.8 pmol/mg protein) sites associated with voltage-sensitive sodium channels in mouse brain vesicle preparations. DDT stimulated the specific binding of 20 n M [ 3 H] BTX-B , producing half-maximal enhancement at 14 μ M and maximal (2-fold) enhancement at 100 μ M. Equilibrium saturation studies of [ 3 H] BTX-B binding in the presence of 100 μ M DDT showed that this compound produced a 1.8-fold increase in the affinity of sodium channels for [ 3 H] BTX-B ( K d = 43 n M) but had little effect on binding capacity ( B max = 5.8 pmol/mg protein). Kinetic studies revealed that the increase in affinity resulted primarily from a decrease in the rate of dissociation of the ligand-receptor complex. These findings show that [ 3 H] BTX-B is a useful allosteric probe of the binding of DDT to its site of action on sodium channels.