Promising Target Research Articles

Microglial Lyzl4 Facilitates β‐Amyloid Clearance in Alzheimer's Disease

AbstractAlzheimer's Disease (AD) is a neurodegenerative condition characterized by the accumulation and deposition of amyloid‐β (Aβ) aggregates in the brain. Despite a wealth of research on the toxicity of Aβ and its role in synaptic damage, the mechanisms facilitating Aβ clearance are not yet fully understood. However, microglia, the primary immune cells of the central nervous system, are known to maintain homeostasis through the phagocytic clearance of protein aggregates and cellular debris. In this study, RNA sequencing analysis and live cell functional screens are employed to uncover microglial genetic modifiers related to AD. Lyzl4 is identified, which encodes a c‐type lysozyme‐like enzyme primarily localized to microglial lysosomes, as a gene significantly upregulated in AD microglia with aging and propose that Lyzl4 upregulation acts as a positive regulator of Aβ clearance. Furthermore, it is found that Lyzl4 overexpression boosts Aβ clearance both in vitro and in vivo, underscoring its potential for mitigating Aβ burden. These novel insights position Lyzl4 as a promising therapeutic target for Alzheimer's disease, paving the way for further exploration into potential AD treatments.

Deficiency of FABP7 Triggers Premature Neural Differentiation in Idiopathic Normocephalic Autism Organoids

AbstractAutism spectrum disorder (ASD), which is caused by heterogeneous genetic and environmental factors, is characterized by diverse clinical phenotypes linked to distinct pathological mechanisms. ASD individuals with a shared clinical phenotype might contribute to revealing the molecular mechanism underlying ASD progression. Here, it is generated induced pluripotent stem cell (iPSC)‐derived cerebral organoids from normocephalic individuals with ASD in a prospective birth cohort with a shared clinical diagnosis. Multiple cell lines and time series scRNA‐seq combined with a histomorphological analysis revealed premature neural differentiation of neural stem cells (NSCs) and decreased expression of Fatty acid binding protein 7 (FABP7) in ASD organoids. It is subsequently revealed alterations in the phosphorylation levels of Mitogen‐Activated Protein Kinase Kinase 1/2 (MEK1/2), which are downstream of FABP7, and the regulation of the FABP7/MEK pathway reversed improper neural differentiation in the ASD organoids. Moreover, both Fabp7‐knockdown and MEK2‐overexpressing mice exhibited repetitive stereotyped behaviors and social defects relevant to autism. This study reveals the role of the FABP7/MEK pathway in abnormal NSC differentiation in normocephalic individuals with ASD, which might provide a promising therapeutic target for ASD treatment.

Ascorbate peroxidase modulation confirms key role in Leishmania infantum oxidative defence

Abstract Background Ascorbate peroxidase (APX) has emerged as a promising target for chemotherapy because of its absence in humans and crucial role in the antioxidant defence of trypanosomatids. APXs, which are class I haeme-containing enzymes, reduces hydrogen peroxide using ascorbate to produce water and monodehydroascorbate, thereby preventing cell damage caused by H2O2. Methods We aimed to create an APX-knockout L. infantum line using CRISPR/Cas9. Despite unsuccessful attempts at full knockouts, we achieved deletion of chromosomal copies post-APX episomal insertion, yielding LiΔchrAPX::LbAPX parasites. We performed phenotypic characterization to assess the impact of these genetic modifications, which included the determination of APX transcript expression levels using quantitative PCR, drug sensitivity, infectivity, and parasite survival in macrophages. Results Quantitative polymerase chain reaction (PCR) analysis revealed a 10- to 13-fold reduction in APX transcript expression in LiΔchrAPX::LbAPX compared with wild-type (LiWT) and APX-overexpressing (Li::Cas9::LbAPX) parasites, respectively. The episomes in those knockdown parasites remained stable even after 20 drug-free passages in vitro. Li::Cas9::LbAPX parasites showed increased resistance to trivalent antimony (SbIII) and isoniazid, reduced tolerance to H2O2, and unchanged macrophage infectivity compared with LiWT. In contrast, LiΔchrAPX::LbAPX parasites were more sensitive to SbIII and isoniazid, exhibited greater susceptibility to H2O2-induced oxidative stress, and 72 h post-infection, showed fewer infected macrophages and intracellular amastigotes compared with LiWT parasites. Conclusions Our findings hint at the indispensability of APX in L. infantum and raise the possibility of its potential as a therapeutic target for leishmaniasis. Graphical Abstract

Therapeutic advances in the targeting of ROR1 in hematological cancers

AbstractReceptor tyrosine kinases (RTKs) are key cell surface receptors involved in cell communication and signal transduction, with great importance in cell growth, differentiation, survival, and metabolism. Dysregulation of RTKs, such as EGFR, VEGFR, HER2 or ROR, could lead to various diseases, particularly cancers. ROR1 has emerged as a promising target in hematological malignancies. The development of ROR1 targeted therapies is continuously growing leading to remarkable novel therapeutical approaches using mAbs, antibody-drug conjugates, several small molecules or CAR T cells which have shown encouraging preclinical results. In the hematological field, mAbs, small molecules, BiTEs or CAR T cell therapies displayed promising outcomes with the clinical trials data encouraging the use of anti-ROR1 therapies. This paper aims to offer a comprehensive analysis of the current landscape of ROR1-targeted therapies in hematological malignancies marking the innovative approaches with promising preclinical and clinical. Offering a better understanding of structural and functional aspects of ROR1 could lead to new perspectives in targeting a wide spectrum of malignancies.

Abstract B014: NRF2 regulation of the immune microenvironment in breast cancer

Abstract Immune checkpoint inhibitors (ICIs) have emerged as a significant advance in the treatment of various cancer types, including breast cancer, though their efficacy varies widely depending on the cancer subtype and the stage of the disease. Following their initial approval in metastatic triple-negative breast cancer (TNBC), ICIs have shown promising results in other contexts, including early-stage cancers and ER+ and HER2+ subtypes. However, even in advanced TNBC the objective response rate to monotherapy ICI is only ∼20%. These results highlight the need to better understand determinants of ICI response in breast cancer. A detailed, high-resolution definition of the tumor immune microenvironment (TIME) will be critical for predicting and engineering effective responses to ICIs. In previously published work, we and others found that the antioxidant transcription factor NRF2 is constitutively active in breast cancer and is associated with tumor recurrence, metastasis, and poor prognosis. However, the mechanisms through which NRF2 promotes breast cancer progression remain unclear. In the current study, we explore the role of NRF2 in reshaping the TIME and its impact on breast cancer progression using preclinical models, flow cytometry, and transcriptomic analyses. We find that NRF2 is constitutively activated in a subset of human and mouse breast cancers where it functions to suppress inflammatory gene expression. In models of recurrent and metastatic mammary tumors, NRF2 knockdown results in a marked reduction in tumor growth rates. Furthermore, the NRF2 inhibition significantly alters the composition of innate and adaptive immune cell populations within the tumor microenvironment. Cytokine profiling revealed that these immune alterations are associated with increased levels of inflammatory cytokines in NRF2-deficient tumor cells compared to controls. RNA sequencing of tumor cells further supports the observed shifts in the immune landscape associated with NRF2 deficiency. Collectively, our findings demonstrate that the loss of NRF2 impairs tumor growth in part through remodeling the TIME and suggest that NRF2 may be a promising therapeutic target for sensitizing breast cancers to ICIs. Citation Format: Yasemin Ceyhan Ozdemir, James V. Alvarez. NRF2 regulation of the immune microenvironment in breast cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr B014.

Abstract B027: ISG15 modulate cancer cell mechanics and metastasis in breast cancer

Abstract Metastasis in breast cancer is a major challenge for prognosis and effective treatment, primarily because cancer cells can create an immune-suppressive microenvironment that supports their progression and spread. The physical properties of cancer cells significantly influence their metastatic potential and their interaction with the environment. Identifying targets that impact both the physical characteristics of cancer cells, and their microenvironment is crucial for tackling metastatic disease. Interferon-stimulated gene 15 (ISG15), a ubiquitin-like protein, is often overexpressed in breast cancer tissues and is associated with poor prognosis, higher tumor grade, and increased invasiveness. Despite these associations, the precise role of ISG15 and its post-translational modification, ISGylation, in cancer cell behavior and interactions with their microenvironment remains unclear. To explore this, we interrogated the biophysical role of ISG15 by using mouse modeling and in vitro loss of function approaches. We utilized whole- body ISG15-deficient mice and conducted a series of experiments to assess the impact of ISG15 on cancer cell properties and their surrounding environment. Our preliminary results indicate that cells lacking ISG15 exhibit altered physical traits, such as increased stiffness and size, which may influence their metastatic behavior. Additionally, targeting ISG15 or disrupting ISGylation enhances the susceptibility of cancer cells to immune cell-mediated destruction. In ISG15- deficient mice, we observed significantly reduced tumor growth and metastasis compared to wild-type controls. These findings suggest that ISG15 modulates critical aspects of cancer cell behavior and their interactions with the microenvironment, contributing to immune evasion and metastatic spread. Our research highlights ISG15 as a promising therapeutic target and provides a foundation for developing new strategies to prevent and treat metastatic cancer Citation Format: Mohamed Haloul, Priya Shah, Vinay Pai, Faruk Hossen, James James Lee, Ekrem Emrah Er. ISG15 modulate cancer cell mechanics and metastasis in breast cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr B027.

Abstract IA016: Vascular control of metastasis

Abstract The molecular analysis of tumor vessel interactions during tumor progression and metastasis has primarily focused on the study of tumor cell-derived angiogenic and lymphangiogenic signals with the purpose to exploit such factors as therapeutic targets. Angiogenic factors activate endothelial cells in nearby blood and lymphatic capillaries to sprout towards the tumor. Tumor angiogenesis thereby not only nourishes the growing tumor, but access to the blood and lymphatic vasculatures enables cells from the primary tumor to enter the circulation to eventually form metastases at distant sites. The complex cellular interactions between tumor cells and endothelial cells have in this context mostly been studied from a tumor cell-centric perspective, i.e., the tumor cells send signals to which endothelial cells merely respond. Yet, the past decade has witnessed a fundamental change of paradigm with the discovery that the vascular endothelium does not just respond to exogenous cytokines but exerts active ’angiocrine’ gatekeeper roles controlling their microenvironment in an instructive manner. We have applied the concepts of angiocrine signaling towards the study of tumor progression and metastasis. Employing novel surgical preclinical metastasis models that better mimic tumor progression and the response to therapy as it occurs in humans, we have molecularly dissected vascular endothelial cells in progressing primary tumors as well as in the pre-metastatic and metastatic niches. These experiments were on the one hand aimed at establishing the systems map of endothelial transcriptomic changes during tumor progression and metastasis and on the other hand to identify and validate novel therapeutic targets. This presentation will review recent advances in the field of tumor microenvironment research and present novel angiocrine signaling mechanisms as promising targets of future mechanism-driven anti-metastatic therapy. Citation Format: Hellmut G. Augustin. Vascular control of metastasis [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr IA016.

Exploring the Antiviral Potential of Artemisia annua Through JAK-STAT Pathway Targeting: A Network Pharmacology Approach

Background: Artemisia annua, a plant with antiviral potential, has shown promise against various viral infections, yet its mechanisms of action are not fully understood. This study explores A. annua’s antiviral effects using network pharmacology and molecular docking, focusing on key active compounds and their interactions with viral protein targets, particularly within the JAK-STAT signaling pathway—a critical mediator of immune responses to viral infections. Methods: From the TCMSP database, we identified eight active compounds and 335 drug targets for A. annua, with 19 intersecting targets between A. annua compounds and viral proteins. A protein–protein interaction (PPI) network highlighted 10 key hub genes, analyzed further through Gene Ontology (GO) and KEGG pathways to understand their immune and antiviral roles. ADMET properties of the active compound Patuletin (MOL004112) were assessed, followed by 200 ns molecular dynamics simulations to examine its stability in complex with JAK2. Results: PPI analysis identified JAK2, MAPK3, MAPK1, JAK1, PTPN1, HSPA8, TYK2, RAF1, MAPT, and HMOX1 as key hub genes, with JAK2 emerging as a critical regulator of immune and antiviral pathways. ADMET analysis confirmed Patuletin’s favorable pharmacokinetic properties, and molecular dynamics simulations showed a stable Patuletin-JAK2 complex, with FEL analysis indicating minimal disruption to JAK2’s intrinsic flexibility. Conclusions: These findings highlight JAK2 as a promising target in the antiviral activity of A. annua compounds, particularly Patuletin, supporting its potential as an antiviral agent and providing a foundation for further research on A. annua’s therapeutic applications.

An allosteric inhibitor of RhoGAP class-IX myosins suppresses the metastatic features of cancer cells.

Aberrant Ras homologous (Rho) GTPase signalling is a major driver of cancer metastasis, and GTPase-activating proteins (GAPs), the negative regulators of RhoGTPases, are considered promising targets for suppressing metastasis, yet drug discovery efforts have remained elusive. Here, we report the identification and characterization of adhibin, a synthetic allosteric inhibitor of RhoGAP class-IX myosins that abrogates ATPase and motor function, suppressing RhoGTPase-mediated modes of cancer cell metastasis. In human and murine adenocarcinoma and melanoma cell models, including three-dimensional spheroid cultures, we reveal anti-migratory and anti-adhesive properties of adhibin that originate from local disturbances in RhoA/ROCK-regulated signalling, affecting actin-dynamics and actomyosin-based cell-contractility. Adhibin blocks membrane protrusion formation, disturbs remodelling of cell-matrix adhesions, affects contractile ring formation, and disrupts epithelial junction stability; processes severely impairing single/collective cell migration and cytokinesis. Combined with the non-toxic, non-pathological signatures of adhibin validated in organoids, mouse and Drosophila models, this mechanism of action provides the basis for developing anti-metastatic cancer therapies.

Interference of small compounds and Mg2+ with dsRNA-binding fluorophores compromises the identification of SARS-CoV-2 RdRp inhibitors.

The COVID-19 pandemic highlighted the need for the rapid development of antiviral therapies. Viral RNA-dependent RNA polymerases (RdRp) are promising targets, and numerous virtual screenings for potential inhibitors were conducted without validation of the identified hits. Here we have tested a set of presumed RdRp inhibitors in biochemical assays based on fluorometric detection of RdRp activity or on the electrophoretic separation or RdRp products. We find that fluorometric detection of RdRp activity is unreliable as a screening method because many small compounds interfere with fluorophore binding to dsRNA, and this effect is enhanced by the Mg2+ metal ions used by nucleic acid polymerases. The fact that fluorimetric detection of RdRp activity leads to false-positive hits underscores the requirement for independent validation methods. We also show that suramin, one of the proposed RdRp inhibitors that could be validated biochemically, is a multi-polymerase inhibitor. While this does not hinder its potential as an antiviral agent, it cannot be considered an specific inhibitor of SARS-CoV-2 RdRp.

The microbiota-gut-brain axis: a potential target in the small-molecule compounds and gene therapeutic strategies for Parkinson's disease.

Parkinson's disease (PD) is a common neurodegenerative disorder characterized by motor symptoms and non-motor symptoms. It has been found that intestinal issues usually precede motor symptoms. Microorganisms in the gastrointestinal tract can affect central nervous system through the microbiota-gut-brain axis. Accumulating evidence has shown that disturbances in the microbiota-gut-brain axis are linked with PD. Thus, this pathway appears to be a promising therapeutic target for treatment of PD. In this review, we mainly described gut dysbiosis in PD and their underlying mechanisms for mediating neuroinflammation and peripheral immune response in PD pathology and futher discussed the potential small-molecule compounds and genic therapeutic strategies targeting the microbiota-gut-brain axis and their applications in PD. Studies have found that some small molecule compounds and alterations of inflammation-related genes can improve the motor and non-motor symptoms of PD by improving the microbiota-gut-brain axis, which may provide potentially beneficial drugs and molecular targets for the therapies of PD.

Unveiling the role of Pleckstrin-2 in tumor progression and immune modulation: insights from a comprehensive pan-cancer analysis with focus on lung cancer.

Cancer remains a leading cause of mortality globally, highlighting the need for novel biomarkers to enhance prognosis and therapeutic strategies. Pleckstrin-2 (PLEK2), a member of the pleckstrin family, has been implicated in processes critical to tumor progression, but its role across cancers remains underexplored. This study systematically examined the expression patterns, prognostic relevance, and functional impact of PLEK2 across multiple cancer types. Using data from The Cancer Genome Atlas (TCGA), Genotype Tissue Expression Project (GTEx), and the Human Protein Atlas, we analyzed PLEK2 expression in both cancerous and normal tissues, revealing significant overexpression of PLEK2 in various cancers at the mRNA and protein levels. Single-cell RNA sequencing further indicated predominant expression of PLEK2 in tumor cells and macrophages within the tumor microenvironment. Survival analysis demonstrated that elevated PLEK2 expression correlated with poor prognosis in specific cancers, though its impact varied across cancer types. Functional assays showed that PLEK2 knockdown inhibited proliferation and migration in human cancer cell lines. In vivo studies using a Lewis lung carcinoma (LLC) model confirmed that PLEK2 knockdown suppressed tumor growth and enhanced the efficacy of PD-1 immunotherapy. Mechanistically, PLEK2 knockdown was associated with reduced AKT pathway activation, diminished tumor-associated macrophage infiltration, and increased CD8 T cell presence. Compounds like Navitoclax were also identified as potential PLEK2 inhibitors. In conclusion, PLEK2 played a multifaceted role in cancer progression and immune response modulation. Targeting PLEK2 might suppress tumor growth and overcome immunotherapy resistance, offering a promising biomarker and therapeutic target to improve cancer treatment outcomes.

Targeting Candida albicans O-acetyl-L-homoserine sulfhydrylase (Met15p) in antifungal treatment.

Fungal infections are a serious threat to public health as they are becoming increasingly frequent. A major problem stems also from a rising fungal resistance to currently available antifungal therapies, therefore novel molecular targets are highly desirable. Exploration of enzymes participating in the biosynthesis pathways of essential amino acids such as L-methionine (L-Met) may provide new insights into pharmaceutical development. The MET15 gene from Candida albicans, encoding O-acetyl-L-homoserine sulfhydrylase (Met15p), an enzyme catalyzing the second step in that pathway, was cloned and expressed in two versions: as N and C-terminal oligo-His-tagged fusion proteins. The recombinant enzymes revealed appropriate activity, and catalyzed conversion of O-acetyl-L-homoserine and a sulfide ion to produce L-homocysteine. A new RP-HPLC-DAD method, using the enzymatic reaction product pre-column derivatization with 5,5'-dithio-bis-(2-nitrobenzoic acid) was developed and used by us to determine Met15p activity. Newly synthesized compounds as well as two commercially available exhibited a Met15p inhibitory effect which was related to antifungal activity. Fungal cells' sensitivity to inhibitors depending on the presence or absence of L-Met in the medium clearly indicated Met15p targeting. Moreover, the synergistic effect of the first methionine biosynthetic enzyme affecting inhibitor and Met15p inhibitors indicate that methionine biosynthesis pathway enzymes are promising molecular targets.

Targeting the mTOR-Autophagy Axis: Unveiling Therapeutic Potentials in Osteoporosis

Osteoporosis (OP) is a widespread age-related disorder marked by decreased bone density and increased fracture risk, presenting a significant public health challenge. Central to the development and progression of OP is the dysregulation of the mechanistic target of the rapamycin (mTOR)-signaling pathway, which plays a critical role in cellular processes including autophagy, growth, and proliferation. The mTOR-autophagy axis is emerging as a promising therapeutic target due to its regulatory capacity in bone metabolism and homeostasis. This review aims to (1) elucidate the role of mTOR signaling in bone metabolism and its dysregulation in OP, (2) explore the interplay between mTOR and autophagy in the context of bone cell activity, and (3) assess the therapeutic potential of targeting the mTOR pathway with modulators as innovative strategies for OP treatment. By examining the interactions among autophagy, mTOR, and OP, including insights from various types of OP and the impact on different bone cells, this review underscores the complexity of mTOR’s role in bone health. Despite advances, significant gaps remain in understanding the detailed mechanisms of mTOR’s effects on autophagy and bone cell function, highlighting the need for comprehensive clinical trials to establish the efficacy and safety of mTOR inhibitors in OP management. Future research directions include clarifying mTOR’s molecular interactions with bone metabolism and investigating the combined benefits of mTOR modulation with other therapeutic approaches. Addressing these challenges is crucial for developing more effective treatments and improving outcomes for individuals with OP, thereby unveiling the therapeutic potentials of targeting the mTOR-autophagy axis in this prevalent disease.

Parkin paves the path to antitumor immunity: Expanding Parkin's role as a tumor suppressor.

Parkin, a ring-between-ring-type E3 ubiquitin ligase, first shown to play a critical role in autosomal recessive juvenile Parkinsonism, has recently emerged as a key player in cancer biology. Parkin is now known to serve as a tumor suppressor, and its deregulation frequently promotes tumorigenesis. In this issue of the JCI, Perego et al. expand that role by showing that Parkin expression stimulated an interferon (IFN) response to modulate CD8+ T cell activity. These findings suggest that, in addition to directly inhibiting tumor progression, Parkin enhances antitumor immune responses, highlighting it as a promising therapeutic target for cancer treatment.

Discovery of Selective PDE1 Inhibitors with Anti-pulmonary Fibrosis Effects by Targeting the Metal Pocket.

Idiopathic pulmonary fibrosis (IPF) is a fatal lung disease with no ideal drugs. Our previous research demonstrated that phosphodiesterase 1 (PDE1) could be a promising target for the treatment of IPF. However, only a few selective PDE1 inhibitors are available, and the mechanism of recognition between inhibitors and the PDE1 protein is not fully understood. This study carried out a step-by-step optimization of a dihydropyrimidine hit Z94555858. By targeting the metal pocket of PDE1, a lead compound 3f was obtained, exhibiting an IC50 value of 11 nM against PDE1, moderate selectivity over other PDEs, and significant anti-fibrotic effects in bleomycin-induced pulmonary fibrosis rats. The structure-activity relationship study aided by molecular docking revealed that forming halogen bonds with water in the metal pocket greatly enhanced the PDE1 inhibition, providing a novel strategy for further rational design of PDE1 inhibitors.

CDH2 and CDH13 as potential prognostic and therapeutic targets for adrenocortical carcinoma

ABSTRACT Cadherin 2 (CDH2, N-cadherin) and cadherin 13 (CDH13, T-cadherin, H-cadherin) affect the progress and prognoses of many cancers. However, their roles in adrenocortical carcinoma (ACC), a rare endocrine cancer, remain unclear. To decipher the roles of these proteins in ACC and to identify their regulatory targets, we analyzed their expression levels, gene regulatory networks, prognostic value, and targets in ACC, using various bioinformatic analyses. CDH2 was strongly downregulated and CDH13 was strongly upregulated in patients with ACC; the expression levels of these genes affected the prognosis. In 75 patients, the expression of CDH2 and CDH13 was altered by 8% and 5%, respectively. CDH2 and CDH13, as well as their neighboring genes, were predicted to form a complex network of interactions, mainly through coexpression and physical and genetic interactions. CDH2 and its altered neighboring genes (ANGs) mainly affect tumor-related gene expression, cell cycle, and energy metabolism. The regulation of tumor-related integrin function, gene transcription, metabolism, and amide and phospholipid metabolism are the main functions of CDH13 and its ANGs. MiRNA and kinase targets of CDH2 and CDH13 in ACC were identified. CDH13 expression in patients with ACC was positively associated with immune cell infiltration. Anti-PD1/CTLA-4/PD-L1 immunotherapy significantly downregulated the expression of CDH13 in patients with ACC. Foretinib and elesclomol were predicted to exert strong inhibitory effects on SW13 cells by inhibiting the expression of CDH2 and CDH13. These data indicate that CDH2 and CDH13 are promising targets for precise treatment of ACC and may serve as new biomarkers for ACC prognosis.

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

Computational engineering of water-soluble human potassium ion channels through QTY transformation.

Transmembrane potassium ion channels are crucial for ion transport, metabolism, and signaling, and serve as promising targets for anti-cancer therapies. However, their hydrophobic transmembrane nature requires detergents, posing a major bottleneck for experimental handling. In this paper, we present a structural bioinformatics study of six experimentally determined and twelve modeled potassium channel structures, in which hydrophobic amino acids (L, I/V, and F) were systematically replaced with neutral hydrophilic ones (Q, T, and Y), making the proteins more water-soluble. QTY (computationally predicted) and native (experimental and repredicted) variants show remarkable structural similarity (RMSD: ~0.50 Å - ~2.14 Å) despite significant sequence differences. QTY variants, both rigid and refined with MD simulations, maintain comparable to native variants stability, solvent-accessible surface area (SASA), and ionic, aromatic, and van der Waals interactions but differ in the grand average of hydropathy (GRAVY), solubility, and hydrophobic contacts. Overall, our study presents a computational approach for designing hydrophilic potassium ion channels while maintaining the native global structure that could potentially simplify their practical use by eliminating the need for detergents.

Hippocampal exosomes from stroke aggravate post-stroke depression by regulating the expression of proBDNF and p75NTR and altering spine density.

Post-stroke depression (PSD) affects millions of patients who suffer cerebral stroke. However, the molecular mechanisms and pathophysiology are poorly understood. Previous studies have shown that exosomes have been proven to be involved in neuropsychiatric disorders such as stroke and post-stroke depression in neurotransmitter release, neuronal remodeling, and neuron angiogenesis. Here we extracted and purified hippocampal exosomes from stroke mouse model to investigate mechanisms of hippocampal exocytosis in PSD assessed by using behavioral tests and biochemical methods. Aiming at the effect of hippocampal exosomes from stroke on the development of PSD, behavioral test was compared including sugar water preference experiment, open fields, forced swimming test, to explore it in depth. Further, the expression of depression-related protein (proBDNF and p75NTR) and synapse-associated proteins (Synaptotagmin and PSD95) was evaluated by Western blotting, RT-qPCR or immunofluorescence staining. Density of dendritic protrusions of neurons was assessed by Golgi staining to measure changes in spine density after the treatment of hippocampal exosomes from stroke. Our results revealed that injection of exosomes from stroke models significantly aggravated depressive-like behaviors, increase of depression-related protein (proBDNF and p75NTR) expression and deficiency of synapse-associated proteins (Synaptotagmin and PSD95) expression, and the decreased number of spin density. Our findings together suggest that hippocampal exosomes from stroke cause exacerbation of depressive-like behavior in mice, possibly resulting from the regulation of neurogenesis by its depression-associated proteins (proBDNF and p75NTR). Therefore, hippocampal exosomes from stroke are promising targets for the diagnosis and treatment of PSD.