Search Results (3,979)

Background: Recently, compounds such as pyrimidine, pyridazine, 1,2,4-triazepine, 1,3,4,6-oxatriazepine, pyridazino[1,2-a]pyrimidine, and pyridazino[1,2-c] pyrimidine, as well as their derivatives, have attracted attention due to their diverse biological activities. Objective: This study focuses on the synthesis of new heterocyclic compounds that feature a seven-membered ring, including pyridazinopyrimido[2,1-c] [1,2,4]triazepine-tetraones (4), pyridazinopyrimidotriazepine-triones (5–8), aminopyri-dazinopyrimido[2,1-c][1,2,4]triazepine-tetraone (9), and 6-amino-8-imino-pyridazino pyrimido[2,1-c] [1,2,4]triazepine-trione (10). These new compounds were synthesized starting from 1-(4-oxo-1,4-dihydropyrimidine)-1,2-dihydropyridazine-3,6-dione (3) and were then evaluated for their antimicrobial activity. Methods: A new series of pyridazino[1,2-a]pyrimido[2,1-c][1,2,4]triazepines and 1,3,4,6-oxatriazepines were synthesized using modern techniques and advanced technology, achieving yields between 72% and 90%. Results: All new compounds were confirmed through IR, ¹H NMR, ¹³C NMR, and mass spectroscopy (MS) and tested for in vitro antimicrobial activity. Compounds (8-10) exhibited excellent antimicrobial activity. Computational analysis provided a comprehensive evaluation of the broad-spectrum inhibitory potential of four lead compounds (6, 8, 9, and 10) against key microbial and fungal targets. These compounds demonstrated consistently superior binding affinities compared to control drugs cefotaxime and nystatin across a range of enzymes essential for pathogen viability and virulence. Conclusions: The structure–activity relationship (SAR) study established a correlation between the tested compounds and their antimicrobial activity. Molecular docking analysis indicated that the in silico results strongly suggest that compounds (6, 8, 9, and 10) are promising multi-target agents capable of disrupting essential bacterial processes and critical fungal pathways, making them excellent candidates for the development of novel antimicrobial therapeutics. These consistent findings support the conclusion that both practical and theoretical studies of the new compounds align with their antimicrobial effectiveness. Full article

Background/Objectives. Antibiotic resistance is an escalating global health concern, highlighting the need for innovative antibacterial strategies beyond traditional drugs. GroEL, a highly conserved bacterial chaperonin essential for protein folding and stress tolerance, represents a promising but underexplored therapeutic target. This study aimed to identify short peptides capable of binding GroEL monomers and potentially altering their function, with the long-term goal of disrupting bacterial survival mechanisms. Methods. A phage display screening of a 12-mer peptide library was performed against purified GroEL monomers, yielding five candidate peptides (G1–G5). Their interactions with GroEL were analyzed through molecular docking and molecular dynamics simulations using three-dimensional GroEL structures (1MNF, 1XCK, 8S32). Stability of binding and interaction profiles were assessed through molecular dynamics-based analyses and MM/GBSA free energy calculations. Results. Peptides G4 and G5 displayed the most stable and energetically favorable interactions, with G4–8S32 showing the strongest binding (−116.68 kcal/mol). These peptides localized near inter-subunit interfaces, suggesting potential interference with GroEL oligomerization or allosteric transitions, which are critical for its biological function. Conclusions. Our findings demonstrate that short peptides can stably bind GroEL and potentially modulate its activity. Peptides G4 and G5 represent at our knowledge the first promising scaffolds for developing a novel class of peptide-based antibacterial agents targeting conserved chaperonin systems. This work introduces a new avenue that warrants further experimental validation. Full article

Cardiovascular diseases (CVDs) represent one of the leading causes of morbidity and mortality in patients with diabetes. However, a correct and effective glycaemic control obtained by pharmacologic interventions, such as the use the novel glucose-lowering agents, demonstrated efficacy in reducing the risk of both cardiovascular events and mortality. The latest classes of glucose-lowering drugs introduced in the clinical practice are DPP4 inhibitors (sitagliptin, saxagliptin, vildagliptin, linagliptin, and alogliptin), GLP-1 receptor agonists (semaglutide, liraglutide, albiglutide, dulaglutide, exenatide, and lixenatide), and SGLT-2 inhibitors (empaglifozin, canaglifozin, and dapaglifozin). Multiple lines of evidence show that all these new drugs associated with the treatment of diabetic disease have the same effectiveness as the traditional antidiabetic drugs, and excellent cardiovascular safety, highlighting their potential in significantly reducing major cardiovascular events and mortality. The aim of our review is to summarise the clinical efficacy of these recently introduced drugs to optimise treatment strategies, especially in the early phase of diabetic disease. Full article

Background: Recently, data have been published about the inhibitory effect at low nanomolar concentrations on the TRPV1 ion channel for a new indole derivative named SV-1010. This molecule has also been shown to have a strong analgesic effect in mice and rats. Since the biological target of SV-1010 is the TRPV1 ion channel, which plays an active role in inflammation, we conducted a series of animal tests to evaluate its potential as an anti-inflammatory agent. Methods: Nine different inflammatory agents were used to assess acute inflammation, and diclofenac was chosen as a positive control. Additionally SV-1010 effects in chronic proliferative and immunogenic inflammation models were also measured. Results: SV-1010 demonstrated a significant effect in most inflammatory tests, often surpassing that of diclofenac, and showed comparable efficacy to several other recognized anti-inflammatory drugs under certain conditions. The level of pro-inflammatory cytokines, TNF-α, IL-1β, and IL-6, exceeded after LPS administration was normalized to the non-LPS control group level by a dose of 0.1 mg/kg of SV-1010, and the effect was comparable to that of diclofenac at a dose of 12.5 mg/kg. The estimation by qPCR of the content of two enzymes, COX-2 and iNOS, which were increased by 10.8- and 19.4-fold, respectively, after LPS induction showed different molecular targets being utilized, manifested in the normalization of COX-2 content only after diclofenac treatment, and iNOS content only after SV-1010 treatment. Conclusions: Due to the simplicity of synthesis and low effective dose for mammal treatment, this compound can be interesting for a practice. Full article

Background/Objectives: Cervical cancer remains a major global health challenge, and treatment resistance limits the long-term success of chemotherapy. Drug repurposing strategies offer new opportunities for improving therapeutic outcomes by combining existing agents with established chemotherapeutics. Sitagliptin, a DPP-4 inhibitor commonly used in type 2 diabetes, has recently gained attention for its potential anticancer effects. This study aimed to investigate the cytotoxic, apoptotic, and anti-metastatic effects of sitagliptin and doxorubicin, individually and in combination, on human cervical cancer cells (HeLa), and to determine whether their combined use exerts a synergistic anticancer effect. Methods: HeLa cells were treated for 48 h with increasing concentrations of sitagliptin, doxorubicin, or their combination. Cell viability was assessed using the MTT assay. Apoptosis was evaluated by Annexin V-FITC/PI staining and caspase-8/9 activity assays. Synergy was quantified using the Chou–Talalay method, and Combination Index (CI) values were used to determine synergistic interactions. Intracellular ROS levels were measured using the DCFDA assay. Migration and invasion capacities were analyzed using wound healing and Transwell assays. MMP-1, MMP-2, TIMP-1, and TIMP-2 levels were quantified via ELISA with normalization to viable cell counts. Gene expression levels of PI3K/Akt and MAPK/ERK pathway components were measured by qRT-PCR. Bioinformatic analyses (STRING, GeneMANIA, GO, KEGG) were performed to identify common molecular targets and enriched pathways affected by both agents. Results: The combination of sitagliptin and doxorubicin significantly reduced cell viability and demonstrated a synergistic interaction (CI < 1). Combined treatment induced a marked increase in ROS production and significantly elevated apoptosis rates compared to monotherapies. Caspase-8 and caspase-9 activities were also higher in the combination group. Migration and invasion assays revealed substantial suppression of cell motility and invasive capacity. After normalization to viable cell numbers, MMP and TIMP reductions remained significant, confirming true biological inhibition rather than cell-death–related artifacts. qRT-PCR analyses showed downregulation of Akt and ERK expression, indicating suppression of key survival and proliferation pathways. Bioinformatic analyses supported these findings by highlighting enrichment in apoptotic, oxidative stress, and metastasis-related pathways. Conclusions: Sitagliptin enhances the anticancer efficacy of doxorubicin by amplifying ROS-mediated apoptosis, inhibiting migration and invasion, and modulating PI3K/Akt and MAPK/ERK signaling in cervical cancer cells. The combination exhibits a clear synergistic effect and demonstrates strong potential as a supportive therapeutic strategy. These findings warrant further in vivo and clinical-level investigations to evaluate the translational applicability of sitagliptin in cervical cancer therapy. Full article

Breast cancer remains the most common malignancy and one of the leading causes of cancer-related death among women worldwide. Advances in antibody-based therapies have improved outcomes across all biological subtypes: HER2-positive, triple-negative, and luminal breast cancer. Monoclonal antibodies such as trastuzumab and pertuzumab have established HER2-targeted therapy as a standard of care, while immune checkpoint inhibitors have introduced immunotherapy into the treatment of triple-negative breast cancer. The emergence of antibody–drug conjugates (ADCs), including trastuzumab deruxtecan, sacituzumab govitecan, and datopotamab deruxtecan, has further expanded the available therapeutic options. Bispecific antibodies represent a new generation of agents with the potential to overcome resistance and enhance immune activation. Despite impressive progress, important challenges remain, including resistance mechanisms and the management of treatment-related toxicities. This review summarizes the biological rationale, clinical evidence, resistance mechanisms, and safety profiles of therapies based on monoclonal antibodies, bispecific antibodies, and antibody–drug conjugates in breast cancer. The development of these treatment modalities fosters the implementation of personalized, immunologically informed treatment strategies that are redefining precision oncology in breast cancer. Full article

HIV-1 integrase strand transfer inhibitors (INSTIs) are pivotal to antiretroviral therapy. However, the emergence of drug-resistant mutations necessitates the development of new agents. Here, we present ACC017 as a novel INSTI candidate. ACC017 demonstrated potent activity against the laboratory-adapted HIV-1_IIIB strain (EC₅₀ = 0.59 nM; SI > 34,525) and maintained efficacy against a panel of drug-resistant strains (EC₅₀ range from 0.34 to 9.12 nM) and clinical isolated strains (EC₅₀ range from 0.11 to 1.78 nM). Mechanism of action studies confirmed its ability to inhibit the integrase enzyme (IC₅₀ = 9.19 nM) and effectively block viral genome integration. Notably, in vitro resistance selection primarily yielded D232N and R263K mutations, without the emergence of G140S/A/C/R or Q148H/R/K. This promising profile, combined with synergistic interactions with other antiretroviral drugs, positions ACC017 as a potential therapeutic option. Full article

Major depressive disorder is increasingly recognized as a metabolic–immune disorder in which chronic inflammation diverts tryptophan (Trp) metabolism toward the kynurenine pathway (KP), reducing serotonin synthesis and producing neurotoxic metabolites such as quinolinic acid (QA). Elevated kynurenine (KYN)/Trp ratios and an altered QA/kynurenic acid (KYNA) balance have been consistently reported in depressed individuals, implicating the KP as a key therapeutic target. Exercise provides a unique, translationally relevant intervention: unlike pharmacological agents acting directly on neurotransmission, contracting skeletal muscle acts as a “kynurenine sink” by inducing kynurenine aminotransferases that convert circulating KYN into neuroprotective KYNA, thereby reducing brain KYN uptake and mitigating excitotoxicity. Clinical studies and meta-analyses confirm that aerobic, resistance, and high-intensity training produce antidepressant effects comparable to pharmacotherapy, while also improving cognition, fatigue tolerance, and cardiometabolic function. Beyond KP remodeling, exercise-induced myokines (irisin, IL-6, BDNF, apelin, FGF21) and adipokines (adiponectin, leptin modulators) coordinate systemic anti-inflammatory and neurotrophic adaptations that enhance resilience and brain plasticity. Furthermore, pharmacological “exercise mimetics” and metabolic modulators, such as PPAR agonists, AMPK activators, NAD⁺ boosters, meldonium, trimetazidine, and adiponectin receptor agonists, may be promising adjuncts for patients with low exercise capacity or metabolic comorbidities. This review provides a novel concept, positioning exercise as a systemic antidepressant that breaks the kynurenine lock of depression. Through proper interpretation of skeletal muscle as an endocrine organ of resilience, we integrate molecular, clinical, and translational findings to show how exercise remodels Trp–KYN metabolism and inflammatory signaling and how pharmacological mimetics may extend these benefits. This perspective consolidates scattered mechanistic and clinical data and outlines a forward-looking therapeutic framework that links exercise and lifestyle, metabolism, and drug discovery. We highlight that re-consideration of our understanding of depression, as a whole-body disorder, should provide new opportunities for precision interventions. Full article

Ferroptosis and senescence are unique cellular processes that lead to irreversible cell abnormalities and tissue damage in many diseases, such as cancer, neurodegeneration, cardiac, liver, and kidney damage. Despite distinct differences between the two processes, essential shared features in their causes and development include increased redox iron toxicity and oxidative stress, together with reduced antioxidant capacity, such as decreased glutathione levels and downregulation of glutathione peroxidase. The consequences of these toxicities include increased lipid peroxidation and aggregation, causing cell damage and death in ferroptosis, whereas in senescence, they lead to DNA and other biomolecular damage, resulting in a form of cell growth arrest with specific characteristics, such as the progressive accumulation of senescent cells across tissues in aging. Many potential therapeutic strategies have emerged to regulate ferroptosis and senescence pathways, including targeting and modulating iron toxicity and redox imbalance, and metabolic, transcriptional, genomic, and other associated pathways and factors. Experimental evidence suggests that iron chelating drugs such as deferiprone, deferoxamine, and deferasirox, and other drugs such as sorafenib, may be potential therapeutics for ferroptosis. Similarly, in senescence, in addition to iron chelating drugs that can act as senomorphic and senolytic agents, several other drugs, such as navitoclax and the combination of dasatinib and quercetin, have shown promising results in preliminary clinical trials as senolytic agents, while rapalogs and several nutraceuticals, such as quercetin, have been studied as senomorphic agents. Despite the absence of antioxidant drugs in clinical practice, the development of therapeutic strategies, including the repurposing of iron chelating drugs and the use of natural antioxidants, may be crucial for therapeutic advances in diseases associated with ferroptosis and senescence. The design of new therapeutic strategies based on the modulation of multiple targets, particularly the control of redox iron and oxidative stress toxicity using combinations of iron chelators with other drugs or nutraceuticals, may improve therapeutic outcomes in many diseases associated with ferroptosis, senescence, and aging. In each case, target selection and specific considerations may apply within the context of personalized medicine. Full article

Carboxyxanthones containing carboxylic acid groups linked to lipophilic aromatic rings resemble the key pharmacophoric features of many nonsteroidal anti-inflammatory drugs (NSAIDs). This structural similarity makes them attractive scaffolds for the development of new anti-inflammatory agents. This study describes the production, cytocompatibility, and anti-inflammatory potential of ten carboxyxanthones (1–10) and two intermediates (11–12) by evaluating their effects on key pro-inflammatory mediators, namely interleukin 6 (IL-6) and prostaglandin E2 (PGE₂). As these compounds are produced by distinct mechanisms, their multi-target potential will be evaluated. Carboxyxanthones were obtained by multi-step pathways using different synthetic approaches through classical benzophenone or diaryl ether intermediates synthesis followed by intramolecular acylation. To the best of our knowledge, the synthesis of carboxyxanthones 3 and 5 is described herein for the first time. All tested compounds were cytocompatible with lipopolysaccharide (LPS)-stimulated macrophages. The most notable carboxyxanthones were 3, 4, 7, and 8, which were able to significantly reduce IL-6 production by approximately 60%. Molecular docking simulations between compounds 1–12 and cyclooxygenase-2 were conducted to characterize the structural features underlying molecular recognition, and to identify the most promising candidates for subsequent PGE₂ assays. Carboxyxanthones 3, 5, and 6, as well as intermediate 12, were predicted to be the best. In the human in vitro inflammation model used, carboxyxanthone 6 exhibited the most potent and consistent inhibitory effect on PGE₂ production. At the highest concentration tested (100 µM), it presented an efficacy comparable to that of celecoxib. Carboxyxanthones 3 and 5 demonstrated a biphasic effect, decreasing and increasing PGE₂ production at lower (5, 12.5, and 25 µM) and higher (50 and 100 µM) concentrations, respectively. These results highlight the potential of carboxyxanthones as promising modulators of inflammatory pathways, paving the way for further studies aimed at elucidating their mechanisms of action, optimizing structural features, and assessing their safety and therapeutic potential in relevant disease models. Full article

Cancer remains one of the leading causes of death worldwide, and resistance to conventional therapies underscores the need for the discovery of novel antitumor agents. The ongoing search for novel natural sources offers promising avenues for discovering unique anticancer compounds with new mechanisms of action. One of these natural sources is represented by fungi, a prolific group of endophytic and non-endophytic eukaryotes able to produce bioactive secondary metabolites, many of which exhibit potent antitumor properties. These natural compounds display diverse chemical structures including polyketides, terpenoids, alkaloids, amino acid-derived compounds, phenols, etc. Their mechanisms of action are equally varied, ranging from induction of apoptosis and cell cycle arrest to inhibition of angiogenesis and metastasis. In this review we describe some potential antitumor compounds of fungal origin, together with the characteristics and biosynthesis of three representative types of antitumor compounds produced by filamentous fungi: squalene-derived sterol-type antitumor agents, prenylated diketopiperazine antitumor metabolites and meroterpenoid antitumor compounds. The ongoing scientific debate regarding the presence of paclitaxel biosynthetic genes in fungi is also discussed. As drug resistance remains a challenge in cancer therapy, fungal compounds offer a valuable reservoir for the development of new chemotherapeutic agents with novel modes of action. Full article

Benzimidazole derivatives are a privileged family of heterocyclic compounds that have remarkable structural diversity and find various pharmacological and industrial applications. In this article, we report on their synthetic procedures, ranging from classic condensation methodologies to modern green chemistry methodologies (microwave-assisted methods and catalyst-free methods). The biological significance of these derivatives is discussed, and their anticancer, antimicrobial, anti-inflammatory, antioxidant, antiparasitic, antiviral, antihypertensive, antidiabetic, and neuroprotective activities are reported. This article also reviews recent industrial applications, with special reference to hydrogen storage and environmental sustainability. The latest computational techniques, such as density functional theory (DFT), molecular docking, and molecular dynamics simulation, are particularly emphasized because they can be instrumental in understanding structure–activity relationships and rational drug design. In summary, the present review describes the importance of new benzimidazole derivatives, which are considered a different class of multitarget agents in medicinal chemistry and computational drug design. Full article

Candida biofilms play a critical role in clinical settings, contributing to persistent and device-associated infections and conferring resistance to antifungal agents, particularly in immunocompromised or hospitalized patients. Biofilm formation varies among Candida species, including C. albicans and non-albicans species, such as C. glabrata, C. tropicalis, C. parapsilosis, and C. auris, due to species-specific transcriptional networks that regulate modes of biofilm development, extracellular matrix composition, and metabolic reprogramming. These differences influence biofilm responses to treatment and the severity of infections, which can be further complicated in polymicrobial biofilms that modulate colonization and virulence. Understanding the mechanisms driving biofilm formation and interspecies interactions is essential for developing effective therapies and requires appropriate experimental models. Available models range from simplified in vitro systems to more complex ex vivo and in vivo approaches. Static in vitro models remain widely used due to their simplicity and reproducibility, but they poorly mimic physiological conditions and require careful standardization. Ex vivo tissue models offer a balance between practicality and biological relevance, enabling the study of biofilm physiology, host–microbe interactions and immune responses. In vivo models, primarily in mice, remain the gold standard for testing antifungal therapies, while alternative systems such as Galleria mellonella larvae provide simpler, cost-effective approaches. Advanced in vitro platforms, including organ-on-chip systems, bridge the gap between simplified tests and physiological relevance by simulating fluid dynamics, tissue architecture, and immune complexity. This review aims to examine Candida biofilms across species, highlighting differences in structural diversity and clinical implications, and to provide a guide to the most widely used experimental models supporting studies on Candida biofilm biology for the development of new therapeutic targets or drug testing. Full article

Background: 8-Quinolinol and its derivatives are drawing significant attention across various disciplines due to their remarkable versatility. These compounds are well-known for their exceptional chelating ability, forming stable metal complexes via their nitrogen and oxygen electron donor atoms. This main characteristic determines their broad utility. Biological activity can also be explained by the chelating capacity, which allows 8-quinolinol to bind to essential metal ions such as Fe, Zn, Cu, and others. This chelation disrupts metal-dependent biological processes in target cells or organisms, leading to a range of effects, including antimicrobial, anticancer, antifungal, and neuroprotective activities. On the other hand, the biological activity of pyrazole derivatives is attributed to their heterocyclic structure, which allows for interactions with biological targets that can lead to enzyme inhibition, receptor antagonism, radical scavenging, and other effects. Objective: This work aimed to synthesize and characterize novel diazene compounds derived from 8-quinolinol or 2-methyl-8-quinolinol and pyrazole amines, and to evaluate their antimicrobial and anticancer activities. Methods: The compounds have been synthesized by coupling diazonium salts obtained from the diazotization of heterocyclic amines with 8-quinolinol and its derivative, 2-methyl-8-quinolinol. The careful selection of reaction conditions enabled the synthesis of high-purity products. The compounds were characterized by 1D and 2D NMR, FT-IR spectroscopy, UV-Vis spectroscopy, and LC-HRMS analysis. The biological activity of the newly synthesized compounds was evaluated following the protocols of EU-OPENSCREEN, a European Research Infrastructure Consortium (ERIC) initiative dedicated to supporting early drug discovery. Results: By combining diazonium salts obtained from 3-methyl-1H-pyrazol-5-amine and ethyl 5-amino-3-methyl-1H-pyrazole-4-carboxylate with the aforementioned coupling agents, four novel 8-quinolinol derivatives were synthesized. The further hydrolysis of the ethoxy carbonyl functional group allowed its conversion to a carboxylic functional group, thus expanding the series of new compounds to six members. Several compounds from the series have proven to be biologically active against several human pathogenic microorganisms and the Hep-G2 cancer cell line. Conclusions: The combination of two well-known biologically active scaffolds through a classic diazo coupling reaction allowed the synthesis of novel biologically active compounds, which showed promising results as possible antifungal and anticancer agents. These results represent a foundation for future studies, which will include a broader biological screening and in vivo studies. Full article

Background/Objectives: Microtubule-targeting agents remain foundational components of anticancer chemotherapy, yet their clinical utility is constrained by resistance and toxicity. Methods: Here, we present a theoretical exploration of a plausible “dual” binding pocket that spans the α-tubulin pironetin site and the inter-subunit todalam site. Eight virtual chimeric ligands, each merging key pharmacophoric elements of pironetin and todalam, were constructed and covalently docked to Cys316 of α-tubulin. Results: Covalent docking followed by 200 ns all-atom molecular dynamics simulations revealed that two derivatives (compounds 4 and 8) stably occupy the merged cavity, simultaneously anchoring in the pironetin region via Michael addition and in the todalam region via π-stacking and hydrogen bonding. These hybrids preserved the critical hydrogen-bonding networks of both parent ligands and exhibited low ligand RMSD values (~1.5 Å) and compact radii of gyration throughout the simulations, indicating a tight, persistent binding. Estimated HYDE affinities of 1.5 µM for compound 4 and 17.6 µM for compound 8, calculated with SeeSAR, suggest that covalent engagement can compensate for moderate non-covalent binding scores. Conclusions: In summary, our results provide compelling grounds for developing a new class of α-tubulin inhibitors that engage the hybrid pocket, laying a foundation for the structure-guided synthesis of first-in-class dual-site compounds capable of overcoming resistance to conventional microtubule-targeting drugs. Full article