High Binding Research Articles

Optimized Second-Generation IL-4Rα Inhibition: Structural and Molecular Dynamics Properties of Rademikibart Fab-IL-4Rα Complex

Introduction: Global Burden of Disease studies showed atopic dermatitis (AD) and asthma are the top two immune-mediated inflammatory diseases at younger age [1]. Dupilumab was the initial first-generation interleukin-4 receptor alpha (IL-4Rα) inhibitor for treating both type I and type II IL-4Rα-dependent inflammatory disorders. Following recent clinical trials, rademikibart (previously, CBP-201) emerges as an optimized next-generation human monoclonal antibody with higher binding affinity to IL-4Rα compared to dupilumab [2]. It demonstrated better effect in inhibiting STAT6 intracellular signaling in vitro and provided similar potency inhibiting both IL-4 induced TARC release and IL-4 induced B cell activation [2]. Materials & Methods: X-ray crystallography was used to determine the atomic resolution 3D structure of rademikibart fragment antigen binding (Fab) bound to IL-4Rα. This structure was analyzed and compared computationally with the 2.82 Å resolution crystal structure of dupilumab Fab bound to IL-4Rα (Protein Data Bank Code 6WGL). Molecular dynamics studies on rademikibart and dupilumab bound to IL-4Rα examined the stability of the complexes and effects of amino acid mutations on complex formation. Results: The x-ray crystal structure of rademikibart Fab bound to IL-4Rα was determined at 2.71Å and compared to the complex of dupilumab Fab and IL-4Rα. The rotation angle between dupilumab and rademikibart bound to IL- 4Rα is 59.17°. This rotation enables the epitope of rademikibart, but not dupilumab, on IL-4Rα to overlap more closely with the conserved binding interface utilized by IL-4 and IL-13 cytokines. Molecular dynamics simulations of rademikibart Fab and dupilumab Fab complexed with IL-4Rα showed the third interface loop (residues 148 to 152 in domain 2) of IL-4Rα interacts directly with rademikibart, which is absent in dupilumab/IL- 4Rα complex. This finding is confirmed by analysis of the hydrogen bond interactions at the interface between the antibodies and IL-4Rα, demonstrating superior binding energy for rademikibart. Through single amino acid mutation analysis on rademikibart, we identified residue Y50 on rademikibart as the key residue interacting with IL- 4Rα’s third interface loop. Conclusion: Our data provide a molecular and structural rationale for the enhanced IL-4Rα inhibition by rademikibart over dupilumab, confirming rademikibart as an optimized second-generation IL-4Rα inhibitor.

Radioiodinated Nanobody immunoPET probe for in vivo detection of CD147 in pan-cancer.

To develop the extracellular matrix metalloproteinase inducer (CD147)-targeting therapeutic strategies, accurate detection of CD147 expression in tumors is crucial. Owing to their relatively low molecular weights and high affinities, nanobodies (Nbs) may be powerful candidates for cancer diagnosis and therapy. In this study, we developed a novel CD147-targeted nanobody radiotracer, [124I]I-NB147, which provides guidance for the noninvasive detection of CD147-overexpressing cancers. CD147 expression in human cancers was detected via immunohistochemistry (IHC) on tissue microarrays (TMAs). Western blot (WB) and flow cytometry were used to screen CD147-positive malignant melanoma (MM), triple-negative breast cancer (TNBC), and pancreatic cancer (PCA) cell lines. The CD147 nanobody (NB147) was labeled with [124I]INa using Iodogen as the oxidizing agent and was purified by the PD-10 column. The physicochemical properties, affinity, metabolic characteristics, biodistribution, and immunoPET imaging of [124I]I-NB147 were evaluated Moreover, [18F]F-FDG was used as a control. Finally, CD147 expression analysis was performed via multiplex immunofluorescence (MxIF) and autoradiography on human cancer specimens and tumor-bearing mice tissues. TMAs results revealed that CD147 is highly expressed in MM, TNBC, and PCA. A CD147-specific nanobody, NB147, was successfully generated with excellent in vitro binding characteristics. [124I]I-NB147 was obtained with high radiochemical yield and purity, and was stable for at least 4h in vitro. WB and FCM revealed that CD147 was positive in A375, MDA-MB-435 and ASPC1 cells, whereas SK-MEL-28, 4T1 and BXPC3 cells presented low expression levels. The radio-ELISA results indicated that [124I]I-NB147 had a high binding affinity to CD147. The uptake of [124I]I-NB147 was significantly different between CD147 high-expression cells and CD147 low-expression cells (P < 0.001). The biological half-life of the distribution and clearance phases were 0.05h and 1.58h, respectively. In CD147-positive tumor models, the [124I]I-NB147 accumulated in A375, MDA-MB-435, and ASPC1 tumors, and the uptake value was significantly higher than that of [18F]F-FDG. Uptake in SK-MEL-28, BXPC3, and 4T1 tumors was not clearly observed. Finally, through autoradiography and histological studies, the correlation analysis between tumor uptake and CD147 expression level was determined. The high expression of CD147 in MM, TNBC, and PCA tissuesand in tumor cells was verified. The CD147 nanobody, NB147 was produced and radiolabeled to obtain the immunoPET probe, [124I]I-NB147, which showed high affinity to CD147 and precise visualization for accurate diagnosis of CD147-expressing lesions in different cancers. These results provide insight into the imaging and binding properties of nanobody NB147 over extended periods of time, reinforcing its potential in developing radionuclide therapies for CD147-positive cancer patients.

Biogenic synthesis of silver nanoparticles from Hylocereus undatus peel waste: exploring EGFR inhibition for targeted therapy of cervical and breast carcinomas

Abstract Background Cancer is one of the leading causes of death worldwide, with breast and cervical cancers being the most common among women. Over 100,000 new cases of breast cancer and 510,000 new cases of cervical cancer are diagnosed annually. This study aimed to develop and evaluate an eco-friendly, low-cost method to synthesize silver nanoparticles using Hylocereus undatus (dragon fruit) peel extract for their anticancer activity. Results Silver nanoparticles loaded with Hylocereus undatus fruit peel extract were successfully developed by a green synthesis technique and were optimized by UV–vis spectroscopy. The nanoparticles had an average size of 71.66 nm, a polydispersity index of 0.3754, and a zeta potential of − 38.52, with a spherical shape and 79.5% silver content. Their maximum absorbance was at 448 nm. Further, in vitro anticancer activity via MTT (3-(4, 5-dimethylthiazolyl-2)-2, 5-diphenyltetrazolium bromide) assay was evaluated and the synthesized nanoparticles displayed IC50 values at 23.51 µg/ml and 23.66 µg/ml against Hela and MDA MB 231 cell lines, respectively. Cytocompatibility studies showed high cell viability (≥ 95%) in L929 mouse fibroblast cells, indicating low toxicity. In silico analyses, including network pharmacology and molecular docking, identified kaempferol and quercetin as key anticancer compounds, with epidermal growth factor receptor (EGFR) (PDB ID: IM17) being the most significant protein target. Docking studies performed by using the Glide module of Schrodinger’s software displayed that kaempferol and quercetin had higher binding affinities for EGFR as compared to the standard drug erlotinib, with MET 769 being a crucial binding site. Conclusion Thus, the outcomes suggest that synthesized silver nanoparticles loaded with Hylocereus undatus fruit peel extract could be a potential and promising drug carrier aiding in cancer treatment.

Stellar Thermonuclear Reaction Rates of Proton Radiative Capture by Closed Light Shell Isotopes

Light isotopes, especially closed shell nuclei, have significance in thermonuclear reactions of the Carbon-Nitrogen-Oxygen (CNO) cycle in stars. In this research, 12C(p, γ) 13N and 14N(p, γ) 15O reactions have been calculated by means of Matlab codes to find the reaction rate across a temperature range of 0.006 to 10 GK using non-resonant parts, as well as the astrophysical S- factor S(E) at low energies. It was concluded that the high binding energy of 12C and 14N nuclei make the reaction less probable thus enabling other competitive processes to develop, which enhances the probability of other competitive proton reactions in the CNO cycle.

Potential Inhibitor of DENV-2 Virus Protease (NS2B-NS3): An In-Silico Studies of Anti-Viral Plants

Dengue virus (DENV) is a mosquito-borne pathogen that affects millions of people worldwide. The DENV-2 protease is a vital enzyme responsible for viral replication and is a promising target for antiviral therapy. The objective of the study is to identify potential inhibitors of DENV-2 protease using In-Silico approaches with phytocompounds from ten antiviral plants. Initially, 133 phytoconstituents were collected with anti-dengue properties from previously reported studies which were virtually screened using SWISS ADME for ADME properties. The DENV-2 protease structure (2FOM) was obtained from the Protein Data Bank and molecular docking was performed using AutoDock Vina. The best-scoring compounds were evaluated and top five potential inhibitors with high binding affinity and stability were selected. The top-scoring compounds were Ligand-91 (Terchebin, -8.1 kcal/mol), Ligand-13 (7-desacetyl-7-benzoylgedunin, -7.8 kcal/mol), Ligand-100 (Triterpenoid, -7.8 kcal/mol), Ligand-12 (7-desacetyl-7-benzoylazadiradione, -7.7 kcal/mol), Ligand-20 (Azadirolic acid, -7.7 kcal/mol), Ref.1 (Doxycycline, -6.6 kcal/mol), Ref.2(Monosdenvir, -7.5 kcal/mol), and Ref.3 (Zanamivir, -5.6 kcal/mol). The result of the study shows that 7-desacetyl-7-benzoylazadiradione and 7-desacetyl-7-benzoylgeduninas compounds with high binding affinity for the target protein. These compounds are found in Azadirachta indica making it a promising candidate for further experimental validation and development of antiviral agents against DENV-2. Keywords: Molecular docking, Anti-dengue, Anti-viral, ADME analysis

Two-Step Chemical Vapor Deposition for Fabrication of FAPbI3 Single-Crystal Microsheets with High Exciton Binding Energy.

Hybrid perovskites exhibit highly efficient optoelectronic properties and find widespread applications in areas such as solar cells, light-emitting diodes, photodetectors, and lasers. Here, we report the innovative synthesis of formamidinium lead iodide (FAPbI3) single-crystal microsheets via a two-step chemical vapor deposition (CVD) method. The microsheets exhibit hexagonal and trapezoidal shapes, with hexagonal FAPbI3 growing parallel to the substrate and trapezoidal FAPbI3 growing perpendicular to the substrate. The dominant role of single-exciton recombination in the photoluminescence (PL) of these microsheets is observed, especially pronounced at low temperatures, attributed to the relatively large exciton binding energies of the samples. Calculations reveal exciton binding energies as high as 110.8 meV for hexagonal and 133.3 meV for trapezoidal FAPbI3 single-crystal microsheets, attributed to reduced rotational freedom of the formamidinium (FA) ions. Further investigation into low-temperature phase transitions indicates lower transition temperatures (around 100 K) for these microsheets, suggesting reduced FA ion rotational freedom and consequently higher exciton binding energies.

Live Single-Cell Transcriptional Dynamics in Plant Cells.

Transcriptional reprogramming plays a key role in a variety of biological processes. Recent advances in RNA imaging techniques have allowed to visualize, in vivo, transcription-related mechanisms in different organisms. The MS2 system constitutes a robust method that has been used for over two decades to image multiple steps of a transcript's life cycle from "birth to death" with high spatiotemporal resolution in the animal field. It is based on the high affinity binding of the MS2 bacteriophage coat protein to its RNA hairpin ligands. Despite its broad applicability, a limited number of studies have implemented the system in plants, but without exploiting its full potential. Here, we describe the transposition of the MS2 technique to Arabidopsis. Combined with microfluidics, it allows to visualize the transcriptional repression of a phosphate starvation induced gene (SPX1) upon phosphate refeeding in vivo. The system provided access to the transcriptional response kinetics of individual cells, gene expression heterogeneity, and revealed bursting phenomena in plantae. The described methods provide new insights for multiple applications.

11C]PS13 Demonstrates Pharmacologically Selective and Substantial Binding to Cyclooxygenase-1 in the Human Brain.

Our laboratory recently developed [11C]PS13 as a PET radioligand to selectively measure cyclooxygenase-1 (COX-1). The cyclooxygenase enzyme family converts arachidonic acid into prostaglandins and thromboxanes, which mediate inflammation. The total brain uptake of [11C]PS13, which is composed of both specific binding and background uptake, can be accurately quantified with gold standard methods of compartmental modeling. This study sought to quantify the specific binding of [11C]PS13 to COX-1 in healthy human brain using scans performed with arterial input function at baseline and after blockade by the COX-1-selective inhibitor ketoprofen. Methods: Eight healthy volunteers underwent two 90-min [11C]PS13 PET scans with radiometabolite-corrected arterial input function, at baseline and about 2 h after oral administration of ketoprofen (75 mg). Results: Two-tissue compartment modeling effectively identified the total uptake of radioactivity in the brain (as distribution volume), showing the highest densities in the hippocampus, the occipital cortex, and the banks of the central sulcus. All brain regions exhibited displaceable and specific binding, and thus none could be used as a reference region. Ketoprofen blocked approximately 84% of the binding sites on COX-1 in the whole brain. After full occupancy was extrapolated, the average whole-brain values of [11C]PS13 were 1.6 ± 0.8 mL·cm-3 for specific uptake, 1.7 ± 0.6 mL·cm-3 for background uptake, and 1.1 ± 0.5 for the specific-to-background ratio. The hippocampus had the highest specific-to-background ratio value of 2.7 ± 0.9. Conclusion: [11C]PS13 exhibited high specific binding to COX-1 in the human brain, but its quantification requires arterial blood sampling.

Amorphous Doped Indium Tin Oxide Thin‐Films by Atomic Layer Deposition.Insights into Their Structural, Electronic and Device Reliability

AbstractThin semiconducting films of magnesium doped indium‐ and tin oxide are prepared by thermal atomic layer deposition (ALD). The metal oxide films are deposited at 200 °C from the precursors trimethylindium, tetrakis(dimethylamido)tin, bis(ethylcyclopentadienyl)magnesium and water as oxidant. These thin‐films are observed to be amorphous by electron microscopy and X‐ray diffraction. However, they exhibited a near‐range atomic order with correlation lengths of up to 10 Å, as demonstrated by high energy total scattering at grazing incidence employing synchrotron radiation. Even minor alterations in composition reveal a significant impact on the thin‐film transistor (TFT) device parameters, due to magnesium's high oxygen binding capability and its ability to inhibit the formation of oxygen vacancies, resulting in a decrease of free charge carriers in the material. Stability tests indicate a device degradation after storage in ambient conditions due to water adsorption on the surface, which could be reversed by an additional annealing step which qualify the films as robust. This studie demonstrate the possibility of employing minor amounts of high band gap oxides such as MgO to manipulate and control the electric behavior of the active channel layer performance in inorganic TFT devices.

BEGAN: Boltzmann-Reweighted Data Augmentation for Enhanced GAN-Based Molecule Design in Insect Pheromone Receptors.

Identifying small molecules that bind strongly to target proteins in rational molecular design is crucial. Machine learning techniques, such as generative adversarial networks (GAN), are now essential tools for generating such molecules. In this study, we present an enhanced method for molecule generation using objective-reinforced GANs. Specifically, we introduce BEGAN (Boltzmann-enhanced GAN), a novel approach that adjusts molecule occurrence frequencies during training based on the Boltzmann distribution exp(-ΔU/τ), where ΔU represents the estimated binding free energy derived from docking algorithms and τ is a temperature-related scaling hyperparameter. This Boltzmann reweighting process shifts the generation process toward molecules with higher binding affinities, allowing the GAN to explore molecular spaces with superior binding properties. The reweighting process can also be refined through multiple iterations without altering the overall distribution shape. To validate our approach, we apply it to the design of sex pheromone analogs targeting Spodoptera frugiperda pheromone receptor SfruOR16, illustrating that the Boltzmann reweighting significantly increases the likelihood of generating promising sex pheromone analogs with improved binding affinities to SfruOR16, further supported by atomistic molecular dynamics simulations. Furthermore, we conduct a comprehensive investigation into parameter dependencies and propose a reasonable range for the hyperparameter τ. Our method offers a promising approach for optimizing molecular generation for enhanced protein binding, potentially increasing the efficiency of molecular discovery pipelines.

Identification of Potential Inhibitors of TGFβR1 for the Treatment of Cancer through Structure-Based Virtual Screening and Molecular Dynamics Simulations.

Globally, cancer is one of the leading causes of death. Resistance to conventional medications, such as chemotherapy and radiation, continues to be a significant challenge in the treatment of cancer despite the availability of numerous medicines. Therefore, the highest priority is to hunt for new therapeutic agents. Transforming growth factor-beta is a pivotal regulatory cytokine that exerts significant influence over cellular processes, particularly emphasizing its role in facilitating and modulating cell proliferation. TGF-β receptor 1, identified as the most promising active site of the TGF-β signaling, is a potent drug target site that has garnered wide attention for developing new anticancer agents. The present investigation investigates the potential natural products as TGFβR1 inhibitors. The SB431542 complexed TGFβR1 protein model was used to screen the natural product database to obtain a compound with high binding potential. NPC247629 has emerged as the best-scored compound among all the screened compounds, demonstrating the highest affinity towards the TGFβR1 regarding docking score -17.54 kcal/mol. The all-atoms MD simulation study indicated that all proposed hits are retained inside the receptor in dynamic states. Additionally, principal component and free energy landscape analysis were performed to explore the binding mechanism of top-hit natural products. The best-screened hits, NPC247629 and NPC60735, have excellent binding affinity and hold a massive potential for TGFβR1 inhibition, paving the way for promising future investigations in cancer treatment.

Anticancer, antimicrobial, insecticidal and molecular docking of sarcotrocheliol and cholesterol from the marine soft coral Sarcophyton Trocheliophorum.

The anticancer, antimicrobial, and insecticidal activities of sarcotrocheliol (1) and cholesterol (2) obtained from the soft coral Sarcophyton trocheliophorum (S. trocheliophorum) were intensively studied. According to this study, both compounds 1 and 2 showed potential cytotoxicity towards the human colorectal carcinomaHCT-116 (IC50 10.4, 11.8µg/mL) and human liver carcinoma HepG2 cell lines (IC50 8.8, 12.0µg/mL), respectively. Compounds 1 and 2 were evaluated as potential inhibitors of caspase-3, a member of the cysteine protease family, which is considered a key enzyme in inducing cell apoptosis. Results showed that compounds 1 and 2 have induced apoptosis via up-regulation of caspase-3. Sarcotrocheliol (1) displayed antimicrobial activity against P. aeruginosa (15mm), B. subtilis (15mm), M. luteus (14mm) and C. albicans (15mm), with a MIC of 1.5µg/mL against the reported test microorganisms. On the other hand, cholesterol (2) showed less activity towards P. aeruginosa (10mm), B. subtilis (14mm), S. aureus (12mm) and C. albicans (10mm) with MICs of 3.0, 1.5, 1.5 and 3.0µg/mL against the tested microorganisms, respectively. Larvicidal activity revealed that compounds 1 and 2 induced remarkable toxicity against the third instar larvae of the mosquito, Culex pipiens even at concentration of 2 ppm. Adulticidal activity data showed that tested compounds are distinctly potent toxicants against the housefly, Musca domestica adult females. Overall, compound 2induced much more insecticidal activity than 1, and M. domestica adult females were more sensitive to tested compounds than C. pipiens larvae. Computationally, Density Functional Theory (DFT) analyses revealed that compound 2 had a higher dipole moment and lower band gap energy when compared to compound 1. So, compounds 2 is chemically more reactive and less stable than compound 1. According to the molecular docking study against PDB IDs: 3KJF, 5UHF and 1ACJ, compounds 1 and 2 demonstrated their activity mode as anticancer, antimicrobial, and insecticidal agents. The compounds exerted many interactions and showed high binding to the proteins, recognizing their potential as drug candidates with broad bioactivities.

BS O05 - Prevalence and Patterns of Iron Deficiency in Patients Living with Obesity: Insights from Bariatric Surgery Candidates

Abstract Background Iron deficiency anaemia (IDA) is a recognised complication of obesity, and its associated co-morbidities. Iron deficiency has been implicated in immunologic dysfunction in obesity. However, the patterns of iron deficiency in people with obesity, independent of IDA, and its implications for patients with obesity remain unclear. This study aimed to investigate potential causes of iron deficiency, including relationship with glycaemic control and relationship with systemic inflammation. Relationship between iron deficiency and body mass index (BMI) was also considered. Method A retrospective review of a prospectively maintained database of consecutive patients undergoing bariatric surgery was performed. Pre-operative haematologic assessments were reviewed, and linear regression models were used to identify the associations of iron deficiency in patients with obesity. Statistical analysis was performed using SPSS. 384 consecutive patients over a 2-year time period were included in the analysis. 72.1% of patients were female and the mean age was 49.44±10.2. The mean weight of included patients was 144.1±31.02 kg, and the mean BMI was 50.66±9.61 kg/m2 Results ​2.45% of patients met the criteria for iron deficiency anaemia. However, 15.49 % had low serum iron(&amp;lt;9 mmol/L), 12.1% had low ferritin(&amp;lt;30mg/L), 1.38% had low transferrin(&amp;lt;2g/L), 15.17% had high Total Iron Binding Capacity(&amp;gt;71.6mmol/L), 37.93% had low transferrin saturation(&amp;lt;20%). High BMI was a significant predictor of low serum iron(β=-0.206, p=0.031). Dysregulated glycaemic metabolism(HbA1c and glucose) was not a significant predictor of iron deficiency. Baseline inflammation (elevated CRP) was associated with low serum iron(β=-0.320, p=&amp;lt;0.001) and low transferrin(β=-0.205, p=0.028). Conclusion Iron deficiency in patients with obesity is common, but not iron deficiency anaemia dependent. It does not appear to be linked to patients’ glycaemic regulation, as previously thought. Our findings suggest it may instead be attributable to the systemic inflammation caused by obesity.

VP28 interacts with PmRab7 irrespective of its nucleotide state.

In shrimp aquaculture, white spot syndrome virus (WSSV) infections severely impact production. Previous research highlighted the crucial role of the Penaeus monodon Rab7 (PmRab7) protein in WSSV entry, specifically its interaction with the viral envelope protein VP28. PmRab7 exists in two conformations: GDP-bound (inactive) and GTP-bound (active). This study, using ELISA and isothermal titration calorimetry (ITC), reveals that the PmRab7-VP28 interaction occurs irrespective of the nucleotide binding state of PmRab7. Comparing the binding affinity between VP28 and different PmRab7 conformations, including wild-type (WT, 22.5 nM), a fast nucleotide exchange (L129F, 128 nM), a GDP-bound form (T22N, 334 nM), and a favorably GTP-bound form (Q67L, 1990 nM), PmRab7-WT exhibits the strongest binding affinity, especially at a lower temperature (25°C). The binding of PmRab7-WT and VP28 in the presence of excess nucleotide (WT with excess GDP, 924 nM, and WT with excess GTP, 826 nM) shows a 2-fold higher binding affinity than in the absence (WT, 1920 nM) indicating that the addition of excess nucleotide for PmRab7-WT enhanced the affinity for VP28. Together, these findings support the potential of PmRab7-WT as a promising therapeutic candidate for WSSV control in shrimp. Furthermore, from an industrial point of view, the ITC platform developed to study the VP28-PmRab7 interactions provides a high-throughput method for screening additives for shrimp feed that can inhibit this interaction.

PLNC8 αβ Potently Inhibits the Flavivirus Kunjin and Modulates Inflammatory and Intracellular Signaling Responses of Alveolar Epithelial Cells

PLNC8 αβ is a cationic antimicrobial peptide that previously has been reported to express both antibacterial and antiviral properties. This study aimed to further elucidate the antiviral effects of PLNC8 αβ and its impact on virus-induced cytotoxicity and inflammatory signaling in human alveolar epithelial cells (A549) infected with the flavivirus Kunjin. Complementary in silico analyses using molecular dynamics (MD) simulation were conducted to investigate the mechanism of action of PLNC8 αβ by studying the interaction of PLNC8 α and β with models of a flavivirus membrane and a eukaryotic plasma membrane, respectively. Our findings demonstrated that PLNC8 αβ significantly reduces both extracellular and intracellular viral loads, as confirmed by plaque reduction assays and RT-PCR. The peptide also mitigated virus-induced cytotoxicity and inflammation. Notably, PLNC8 αβ modulated the virus-induced dysregulation of key signaling and inflammatory genes, such as TLR9, TLR3, NOD2, FOS, JUN, IL6, and CXCL8. MD simulation revealed that PLNC8 αβ exhibits higher binding affinity for a flavivirus membrane model compared to a model of the plasma membrane, likely due to stronger electrostatic interactions with anionic phospholipids. This selective interaction possibly accounts for a potent antiviral activity of PLNC8 αβ combined with a minimal cytotoxicity toward human cells. Overall, PLNC8 αβ shows significant promise as an antiviral agent against flavivirus infections and warrants further exploration for peptide-based antiviral therapies.

Abstract 4126333: TRPC6 A404V is a gain-of-function variant associated with doxorubicin-induced cardiotoxicity in patients

Background: Gain-of-function mutations in the canonical transient receptor potential 6 (TRPC6) channel contribute to heart failure (HF) and focal segmental glomerulosclerosis in humans. Our GWAS results indicated that the TRPC6 A404V variant, having a minor allele frequency of 12% in the population, is associated with doxorubicin-induced cardiotoxicity. However, the underlying ionic mechanisms of this variant have not been fully examined. Methods: Combining patch clamp recording, site-directed mutagenesis, and in-silico analysis, we evaluated the TRPC6 A404V variant function. Results: Whole-cell TRPC6 currents were elicited in HEK293 cells using a voltage ramp protocol from -100 mV to +100 mV with a holding potential of -60 mV, 48 hours after transfection with TRPC6 WT or A404V cDNAs. The inward-current densities at -100 mV and the outward-current densities at +100 mV for TRPC6 WT and A404V variant were similar at baseline. However, after exposure to 50 μM 1-oleoyl acetyl-sn-glycerol (OAG, a TRPC6 activator), these current densities were significantly increased by 2.6-fold and 4.5-fold respectively in the WT (n=20 cells), and by 8.4-fold and 8.9-fold respectively in the A404V variant (n=12 cells, p&lt;0.05 vs. WT). The OAG effects were abolished by superfusion with 1 μM BI-749327 (a specific TRPC6 inhibitor). Moreover, a 24-hour treatment with 0.5 μM doxorubicin (DOX) further amplified the effects of OAG, increasing the total inward- and outward-current densities by 7.2-fold and 9.5-fold respectively in TRPC6 WT (n=11 cells), and by 13.9-fold and 14.7-fold respectively in the A404V variant (n=13 cells, p&lt;0.05 vs. WT). In comparison, the OAG effects on TRPC6 WT and A404V channels were not potentiated by treatment with 0.5 μM doxorubicinol (DOXol, a metabolite of DOX) for 24 h (n=10-12 cells, p=N.S.). Molecular docking studies showed that OAG had a lower binding energy (-5.60 kcal/mol) and a smaller apparent equilibrium constant (Kd) of 0.079 mM with the A404V variant, compared to those of -4.49 kcal/mol and 0.511 mM respectively with TTRPC6 WT. Conclusion: TRPC6 A404V is a gain-of-function variant with a higher binding affinity to OAG. Treatment with DOX but not DOXol greatly enhances TRPC6 WT and A404V channel activation by OAG. Thus, cancer patients carrying the TRPC6 A404V variant may be more vulnerable to develop HF upon treatment with anthracycline.

IMMU-08. PRECLINICAL EVALUATION OF GAL-1-SPECIFIC CAR-T CELL FUNCTION IN AN IN VITRO AND EX VIVO MODEL OF GLIOBLASTOMA

Abstract BACKGROUND Human glioblastoma (GBM), especially those exhibiting anti-VEGF resistance, overexpress the carbohydrate-binding protein galectin-1 (Gal-1). To develop novel anti-GBM approaches, we developed Gal-1 targeted CAR-T cells to investigate potential antitumor effect with in vitro and ex vivo slice culture models. METHODS Uniform GBM brain slice cultures were collected using NICO’s Myriad resection tool and their Automated Preservation System (APS), designed to obtain fresh brain tumor samples maintaining tumor cytoarchitecture and microenvironment. To prepare Gal-1 CAR-T cells, we used creative laboratory to utilize a third-generation Gal-1-CAR construct with high binding and codon optimized scFv-Gal-1 fragment fused with CD3ζ and co-stimulatory cytoplasmic domains of CD28 and 4-1BB (Gal-1 scFv-CD28-4-1BB-CD3ζ). We then transfected into the T cells, from peripheral blood, mononuclear cells using a lentiviral system. The anti-tumor capabilities of CAR-T cells were evaluated by co-culturing with GBM cells and ex vivo APS-GBM slices. RESULTS The collected APS- GBM slices samples were clear of debris and blood product, not requiring post-surgical mechanical slices, and exhibited viability up to 12 days over traditionally prepared ex vivo cultures. With this, we found Gal-1-CAR-T cells grew exponentially in the presence of cytokines and maintained phenotypic and biological attributes such as cell viability, potency, migration, and T cell activation. Gal-1 scFv-CD28-4-1BB-CD3ζ -CAR-T cells killed more than 80% of GBM tumor cells within 24 hours in Gal-1+ve, but not Gal-1-ve GBM cells in vitro. Additionally, these CAR-T cells selectively caused significant release of IL-2, IFN-γ and TNF-α only from Gal-1+ve co-cultures and induced significant Gal-1+ve GBM cell death in an ex vivo model without any general toxicity. CONCLUSION Based on in vitro cell culture and ex vivo APS-brain slice culture results, we conclude that the novel Gal-1 scFv-CD28-4-1BB-CD3ζ CAR-T cell therapy may offer an effective therapeutic option. Further pre-clinical and clinical studies need to be performed to validate this novel approach

Molecular modeling and cytotoxic activity studies of oxirane-2-carboxylate derivatives

In this study, five 3-aryloxirane-2-carboxylate derivatives were prepared, and the antiproliferative activities of molecules were screened in lung and colon cancer cell lines. The results showed that molecules had antiproliferative activity on cancerous cells with IC50 values under 100 µM. Furthermore, all of the molecules were found to have a much higher cytotoxic effect than cisplatin in colon cancer cells. The interactions of the relatively active compounds to the crucial enzyme in cancer cell proliferation, cyclin-dependent kinase 1 (CDK1), were investigated using molecular docking. The stability of the resulting CDK1-compound complexes procured from the docking was also assessed through molecular dynamics (MD) simulations. Then, the binding affinity of compounds 2-3a and 2-3c to the target enzyme was computed by MMPBSA. The molecular docking study demonstrated that the two most active compounds could bind to the enzyme. The binding potential of 2-3a is anticipated to be higher as it had one more conventional hydrogen bond and a slightly lower binding energy than compound 2-3c. The MD simulation study exhibited that the two compounds formed a stable complex with the enzyme. On the other hand, the MMPBSA energy computation implicated a slightly higher binding affinity for compound 2-3c toward the enzyme. Furthermore, electrical and frontier molecular orbital analysis of all of the tested compounds was conducted by density functional theory (DFT) studies. Compound 2-3a is anticipated to be the most chemically stable as it gave the highest energy gap value in the DFT analysis.

EXTH-69. DEVELOPMENT OF A NOVEL, HUMAN ANTIBODY TO IMPROVE ONCOLYTIC VIRUS THERAPY FOR GLIOBLASTOMA

Abstract Glioblastoma (GBM) is the most aggressive, malignant, primary brain tumor with abysmal overall survival. GBM is regarded as an “immune cold” tumor due to poor immune cell infiltration and immunosuppressive signaling in the tumor microenvironment (TME). Oncolytic herpes virus (oHSV) therapy has emerged as a possible therapeutic avenue for solid tumors such as GBM. We have observed that oHSV-treated tumor cells release extracellular ATP (eATP) which functions as immunostimulatory signaling molecule. In the TME, eATP is rapidly hydrolyzed into immunosuppressive adenosine by ectoenzymes CD39 and CD73. Using global CD73 knock out (CD73KO) mice or a function-blocking murine antibody, we found that blocking CD73 activity improves oHSV therapy in vivo. Intracranial tumor-bearing CD73KO mice respond significantly better to oHSV therapy than wild type (WT). These long-term survivors also rejected a subsequent tumor challenge, demonstrating development of a memory response. scRNA-seq revealed significantly increased immune cell infiltration in CD73KO mice compared to WT. We evaluated cellular crosstalk using CellChat and uncovered a major CCL-directed signaling pathway in the CD73KO mice. Furthermore, we identified a novel, human CD73 antibody from panning an scFv phage display library derived from human tonsils. This antibody, Ab6, demonstrated functional inhibition of purified CD73 and very high binding affinity for CD73. Co-culture of human GBM cells treated with OV and Ab6 and donor PBMCs resulted in increased tumor cell death. Additionally, human DCs exposed to Ab6 and OV-treated conditioned media were better able to activate T cells. To evaluate in vivo efficacy of this novel antibody, we have generated custom humanized CD73 knock-in mice wherein human CD73 has replaced murine CD73. We are currently evaluating the efficacy of Ab6 and oHSV in these mice against intracranial glioma. These results will support the translation of Ab6 as a potential immune therapeutic to add to the arsenal against brain tumors.

Oral administration of tannic acid attenuates dyslipidemia, hyperglycemia, and oxidative stress in high‐fat and fructose diet‐induced obesity in rats

AbstractObesity and diabetes are considered life‐threatening conditions, characterized by increased oxidative stress, insulin resistance, hepatotoxicity, hyperglycemia, and hypercholesterolemia. Therefore, we studied the effects of tannic acid in a high‐fat and fructose‐diet‐induced rat model of obesity. Administration of tannic acid at doses of 200 and 400 mg/kg significantly reduced fasting blood glucose concentration, reversed disoriented lipid profile, decreased liver enzyme activities, and inhibited oxidative stress compared to the high‐fat, high‐sugar group. Histopathological examination showed preserved pancreas and liver architecture in the tannic acid‐administered groups. The in vitro inhibitory activity of tannic acid against alpha‐amylase, alpha‐glucosidase, and pancreatic lipase showed good inhibitory potential. Molecular docking studies showed high binding affinity and more hydrogen bond interactions between tannic acid and receptor proteins (alpha‐amylase, alpha‐glucosidase, and pancreatic lipase) implicated in obesity and diabetes. In conclusion, tannic acid prevented the onset of oxidative stress, preserved the liver, and restored the disoriented lipid profile in high‐fat and fructose diet‐induced obesity in rats.