Isothermal titration calorimetry determination of thermodynamics of binding of cocaine and its metabolites to humanized h2E2 anti-cocaine mAb

Inhibitory Potential and Binding Thermodynamics of Scyllatoxin-Based BH3 Domain Mimetics Targeting Repressor BCL2 Proteins

The B-cell lymphoma 2 (BCL2) proteins are a class of apoptosis regulators that control the release of apoptogenic factors from mitochondria. Under normal physiological conditions, apoptosis is inhibited through the actions of anti-apoptotic (repressor) BCL2 proteins that bind semi-indiscriminately to the helical BH3 domains of pro-apoptotic (effector) BCL2 proteins. In this work, we developed a series of BH3 domain mimetics by grafting residues from the effector BCL2 protein Bax onto the α-helix of scyllatoxin (ScTx). These so-called "ScTx-Bax" constructs were then used to gain insight into the physicochemical nature of repressor/effector BCL2 interactions. Specifically, we utilized competitive binding and isothermal titration calorimetry (ITC) to investigate the inhibitory potential and binding thermodynamics of ScTx-Bax structural variants that target the repressor protein Bcl-2 (proper) in vitro. Our data show that ScTx-Bax mimetics compete with isolated Bax BH3 domain peptides for Bcl-2 with IC50 values in the mid-nanomolar range and that greater flexibility within the ScTx-Bax BH3 domain correlates with more effective inhibition. Furthermore, ITC experiments revealed that unstructured ScTx-Bax variants target Bcl-2 with greater entropic, but lower enthalpic, efficiencies than structured ScTx-Bax peptides. These results suggest that entropic contributions to binding Bcl-2 are more favorable for flexible BH3 domains; however, this enhancement is counterbalanced by a moderate enthalpic penalty. Overall, this study improves understanding of how structural properties of effector BH3 domains influence the promiscuous binding patterns of BCL2 proteins and expands the utility of ScTx-based BH3 domain mimetics as molecular tools to study discrete recognition elements that facilitate repressor/effector BCL2 interactions.

Decreased solubility and increased adsorptivity of a biotinylated humanized anti-cocaine mAb

Biotinylation of proteins, including antibodies, is a very useful and important modification for a variety of biochemical characterizations, including anti-drug antibody (ADA) assays used to detect antibodies raised against therapeutic antibodies. We assessed different degrees of biotin labeling of an anti-cocaine mAb currently under development for treating cocaine use disorder. We noted that higher levels of biotin labeling dramatically decreased mAb solubility, and increased the tendency to bind to surfaces, complicating characterization of the biotinylated antibody. Specifically, in phosphate buffered saline, labeling stoichiometries of more than about 3 biotin/mAb resulted in decreased recoveries due to increased binding to surfaces and decreased mAb solubility. Native gel agarose electrophoresis, differential scanning fluorimetry, and isothermal titration calorimetry all demonstrated changes in the mAb which became more pronounced above a labeling ratio of 3 biotin/mAb. At 3.0 biotin/mAb, there were minimal changes in solubility, adsorptivity, exposure of hydrophobic dye-binding sites, heat stability, and cocaine binding, in stark contrast to labeling with 5.6 biotin/mAb. Thus, the degree of biotinylation should be kept at about 3 biotin/mAb to maintain antigen binding and general structure, solubility, and stability of this mAb, a finding which may be important for other similar mAbs currently in use or under development.

Exploring the Landscape of Aptamers: From Cross-Reactive to Selective to Specific, High-Affinity Receptors for Cocaine

We reported over 20 years ago MNS-4.1, the first DNA aptamer with a micromolar affinity for cocaine. MNS-4.1 is based on a structural motif that is very common in any random pool of oligonucleotides, and it is actually a nonspecific hydrophobic receptor with wide cross-reactivity with alkaloids and steroids. Despite such weaknesses preventing broad applications, this aptamer became widely used in proof-of-concept demonstrations of new formats of biosensors. We now report a series of progressively improved DNA aptamers recognizing cocaine, with the final optimized receptors having low nanomolar affinity and over a thousand-fold selectivity over the initial cross-reactants. In the process of optimization, we tested different methods to eliminate cross-reactivities and improve affinity, eventually achieving properties that are comparable to those of the reported monoclonal antibody candidates for the therapy of overdose. Multiple aptamers that we now report share structural motifs with the previously reported receptor for serotonin. Further mutagenesis studies revealed a palindromic, highly adaptable, broadly cross-reactive hydrophobic motif that could be rebuilt through mutagenesis, expansion of linker regions, and selections into receptors with exceptional affinities and varying specificities.

Novel partial reduction of the humanized anti-cocaine mAb h2E2 for selective cysteine labeling

Monoclonal antibodies are utilized for treating many diseases and disorders, as well as for basic research and development. Covalent labeling of mAbs is important for various antibody applications and creating antibody drug conjugates. Labeling at reactive lysine residues using lysine selective reagents is useful, but is non-selective and can interfere with antigen binding and interactions of the Fc antibody region. In this work, using an anti-cocaine mAb (h2E2), we utilized triphenylphosphine-3,3',3″-trisulfonic acid (TPPTS), and demonstrated for the first time reduction of disulfides in an antibody by TPPTS. More importantly, this reduction was very reproducible, limited, and selective, and permitted selective labeling of the antibody with a cysteine reactive fluorescent reagent, resulting in labeling of a few specific cysteines. Similar results were obtained using TCEP-agarose reduction. We demonstrated that both of these selective partial reduction methods gave rise to approximately two labels per mAb, mostly by selective reduction of the heavy chain to light chain disulfide bond, as demonstrated by non-reducing SDS-PAGE protein band analysis. Thus, convenient, reproducible, and selective mAb disulfide reduction was achieved under mild conditions. These labeled, partially reduced mAbs were characterized by differential scanning fluorimetry (DSF), detecting the incorporated fluorescein instead of an exogenously added dye, and for antigen (cocaine) binding by isothermal titration calorimetry (ITC). Both the structure and antigen binding of the mAb was maintained. This novel selective reduction and labeling is generally relevant to modification of antibodies and to future development of conjugated mAbs for experimental and therapeutic purposes.

Characterization and optimization of fluorescein isothiocyanate labeling of humanized h2E2 anti-cocaine mAb

Fluorescein isothiocyanate (FITC) is widely used to fluorescently label reactive lysine residues on proteins, including antibodies. The rate and extent of labeling varies with reaction conditions, concentration of label, and the concentration and nature of the protein. Fluorescently labeled proteins are very useful, and one use for FITC labeled mAbs is development of assays to measure anti-mAb antibodies produced in vivo during treatment with antibody therapeutics. Our laboratory has developed a humanized anti-cocaine mAb (h2E2) intended for the treatment of cocaine use disorders. Thus, a well characterized FITC labeled h2E2 mAb is needed to quantitate possible anti-mAb antibodies. The time course of labeling and the relative incorporation of FITC into the heavy and light chains, as well as into the Fab and Fc portions of the mAb, was assessed. A novel use of differential scanning fluorimetry in the absence of any extrinsic fluorophore was developed and demonstrated to be capable of measuring antigen (cocaine) binding. In addition, the effect of increasing degrees of labeling by FITC on the thermodynamic parameters driving the binding of cocaine to the mAb was assessed via isothermal titration calorimetry (ITC). This binding technique, unlike others developed recently to measure cocaine binding, is not dependent on, or subject to interference by, the absorbance or fluorescence of the incorporated FITC label. The methods and results reported herein guide the optimization of FITC labeling needed for anti-mAb assays and other assays important for the development of therapeutic mAbs, which are some of the most specific and clinically useful drugs available.

Eukaryotic Expression of the Cytochrome c Oxidase Subunit I of Sitophilus zeamais and Its Interaction with Allyl Isothiocyanate

Sitophilus zeamais Motschulsky (Coleoptera: Curculionidae) is a destructive pest of stored grains around the world. Allyl isothiocyanate (AITC) was shown to have good bioactivity in the control of S. zeamais. In this study, the interaction of AITC on cytochrome c oxidase core subunits I (COX I) and their binding mechanism were determined using spectroscopic, isothermal titration calorimetry and molecular docking techniques. The results indicate the binding constant (Ka) of AITC and COX I was 6.742 × 103 L/mol. Analysis of spectroscopic revealed that the binding of COX I to reduced Cyt c induced conformational changes of reduced Cyt c, while AITC could competitively bind and inhibit the activity of the COX I protein. Moreover, molecular docking results suggested a sulfur atom in the AITC structure could form a hydrogen bond having a length of 3.3 Å with the Gly- 27 of COX I.

Exploration of the effect of Celastrol on protein targets in nasopharyngeal carcinoma: Network pharmacology, molecular docking and experimental evaluations

Background: Celastrol, an important extract of Tripterygium wilfordii, shows strong antitumor activity in a variety of tumors including nasopharyngeal carcinoma (NPC). However, little is known about its targets in NPC. We aimed to screen the key gene targets of Celastrol in the treatment of NPC by means of in silico analyses (including network pharmacology and molecular docking) and experimental evaluations. Methods: The main target genes of Celastrol and the genes related to NPC were obtained by retrieving the relevant biological databases, and the common targets were screened. Protein-protein interaction analysis was used to screen the hub genes. Then, a "compound-target-disease" network model was created and molecular docking was used to predict the binding of Celastrol to the candidate hub proteins. Afterward, the expression changes of the candidate genes under the administration of Celastrol were verified in vitro and in vivo. Results: Sixty genes common to Celastrol and NPC were screened out, which may be related to numerous biological processes such as cell proliferation, apoptosis, and tube development, and enriched in various pathways such as PI3K- Akt, EGFR tyrosine kinase inhibitor resistance, and Apoptosis. The tight binding ability of the candidate hub proteins (TNF, VEGFA, and IL6) to Celastrol was predicted by molecular docking [Docking energy: TNF, -6.08; VEGFA,-6.76; IL6,-6.91(kcal/mol)]. In vitro experiments showed that the expression of TNF and VEGFA decreased while the expression of IL6 increased in NPC cells (CNE2 and HONE1) treated with Celastrol. In vivo experiments suggested that Celastrol significantly reduced the weight and volume of the transplanted tumors in tumor-bearing mice in vivo. The expression of TNF, VEGFA, and IL6 in the transplanted tumor cells could be regulated by using Celastrol, and the expression trends were consistent with the in vitro model. Conclusion: Several gene targets have been filtered out as the core targets of Celastrol in the treatment of NPC, which might be involved in a variety of signaling pathways. Hence, Celastrol may exert its anti-NPC activity through multiple targets and multiple pathways, which will provide new clues for further research. Future experiments are warranted to validate the findings.