The recent developments of camptothecin and its derivatives as potential anti-tumor agents

A systematic insight into glycycoumarin as potential IL-8/topo I inhibitor from natural products collected in Taibai mountain based on the combination of in silico and bioassay

This study aimed to screen IL-8/topo I inhibitors from natural products collected in Taibai mountain and explore the underlying mechanisms. A natural product library of Taibai mountain (NPTM) was first constructed containing 186 compounds. Then, 15 and 6 potential inhibitors were screened using pharmacophore modeling for IL-8 and topo I, respectively. Molecular docking indicated that glycycoumarin was IL-8/topo I inhibitor. A 200 ns molecular dynamics simulation reflected high binding stability and favorable hydrogen bond interaction within glycycoumarin-IL-8/topo I complexes. MM/GBSA calculation showed that the binding free energy was - 12.81 kcal/mol and - 31.20 kcal/mol, and Pro 32 and DT 10 contributed most to glycycoumarin and IL-8, topo I, respectively. SMD simulation demonstrated a stable binding under physiological conditions with energy demands to dissociate from IL-8/topo I. Glycycoumarin decreased IL-8 production in the inflammatory cells, and exhibited obvious topo I inhibition, as well as strong cytotoxicity to three cancer cells. A PPI network revealed that glycycoumarin might work through proteoglycans in cancer (hsa05205) and IL-17 signaling pathway (hsa04657). These results improved current understanding of natural IL-8/topo I inhibitors from Taibai mountain. The combination of in silico and bioassay could provide a new strategy for exploring natural lead compounds against inflammation and cancer.

Camptothecin-loaded Surface-modified Nanostructured Lipid Carriers Consisting of L-Cysteine- and L-Cystine-derived Lipids: Physicochemical Characterization and In Vitro Evaluation

Camptothecin (CPT) is a potent chemotherapeutic agent used in the treatment of colorectal, breast, ovarian, colon, and stomach cancers. However, its clinical application has been significantly restricted due to several drawbacks, including poor water solubility, nonselective toxicity, drug resistance, and inherent instability. To address some of these challenges and to enhance the stability, solubility, and biological efficacy of CPT, in this work, we have attempted to explore nanoparticulate delivery strategies using nanostructured lipid carriers (NLCs) for the targeted delivery of CPT. We have employed L-cysteine- and L-cystine-derived lipids, C12-cys-C12 and [C12-cys]2, along with isopropyl palmitate, as a co-liquid lipid to produce surface-modified NLCs. L-cystine was incorporated into the lipid structure in order to exploit its redox-sensitive disulfide (S─S) bond for stimuli-responsive delivery of CPT. Sulfur-containing L-cysteine and its oxidized form L-cystine containing S─S bond is expected to enhance anticancer drug delivery by offering improved therapeutic efficacy and biocompatibility over conventional lipids. This was confirmed by the glutathione (GSH) assay. The biocompatibility of NLC formulations was determined by in vitro MTT assay. It has been shown that compared to free CPT and cysteinelated NLC-CPT, the cystinelated NLC-CPT is more effective in killing both human hepatoma (HuH7) and colon carcinoma (Caco-2) cells.

Self-enhanced ROS-responsive camptothecin prodrug nanoparticles elicit safe and efficient intravesical instillation therapy of bladder cancer

Bladder cancer remains a significant clinical challenge, necessitating the development of innovative therapeutic strategies. Recent advancements have highlighted the potential of reactive oxygen species (ROS)-responsive drug delivery systems in cancer therapy. In this study, we introduce a novel treatment approach utilizing a ROS-responsive camptothecin (CPT) prodrug encapsulated within chitosan nanocarrier, named CACPT. Cinnamaldehyde (CA), acting as a ROS generator, forms thioketal bonds with CPT to create a prodrug that responds selectively to the elevated ROS levels within the tumor microenvironment. Upon exposure to high ROS conditions, these thioketal bonds are cleaved, resulting in the simultaneous release of CPT and CA. The liberated CA further enhances ROS production, establishing a positive feedback loop that amplifies the therapeutic effect. The use of amphiphilic chitosan nanocarriers enhances the retention and penetration of the prodrug within bladder tissue, optimizing its therapeutic potential. Our experimental findings demonstrate that this self-enhanced ROS-responsive release promotes increased cellular uptake and significantly enhances the anticancer efficacy of CACPT. These results position CACPT as a promising candidate for orthotopic infusion therapy in bladder cancer, potentially overcoming current limitations in treatment options. The innovative combination of ROS-responsive mechanisms and chitosan nanocarriers represents a paradigm shift in bladder cancer therapeutics, offering a multifaceted approach with substantial promise for clinical translation.

Discovery of homocamptothecin derivative TOP-0618 as a radiosensitive agent for the treatment of pancreatic cancer

BACKGROUND

Pancreatic cancer is one of the most lethal malignancies characterized by a complex tumor microenvironment (TME) and highly heterogeneous nature, making it resistant to radiotherapy. This study aims to evaluate the radiosensitizing effect of homocamptothecin derivative TOP-0618 on pancreatic cancer.

METHODS

Clonogenic assays and cell viability assays were used to evaluate the radiosensitizing effects of TOP-0618 on pancreatic cancer cells. Cell cycle and apoptosis were detected using flow cytometry. A pancreatic bi-flank xenograft tumor model was used to evaluate the radiosensitivity of TOP-0618. H&E staining analyses and TUNEL staining were used to examine necrosis and apoptosis of pancreatic xenograft tumors.

RESULTS

Cytotoxicity assays revealed that IC50 values of TOP-0618 against PANC-1 and MIAPaCa-2 cells were 1.442 µmol/L and 1.198 µmol /L, respectively. Additionally, clonogenic assays revealed that TOP-0618 exerted radiosensitizing effects on both pancreatic cells, and the sensitizer enhancement ratio (SER) of TOP-0618 was 1.14 for the PANC-1 cell line and 1.65 for the MIAPaCa-2 cell line. The preliminary study revealed that TOP-0618 improved radiosensitivity by enhancing G2/M phase arrest and increasing the apoptosis of pancreatic cells. Subsequently, in a pancreatic bi-flank xenograft tumor model, TOP-0618 combined with irradiation significantly inhibited tumor growth, and increased necrosis and apoptosis in pancreatic xenograft tumors.

CONCLUSIONS

Our work demonstrates the radiosensitizing effect of homocamptothecin derivative TOP-0618 on pancreatic cancer both in vivo and vitro, and lays a foundation for clinical transformation.

Antitumor activity of topoisomerase I targeted by camptothecin 7-propionyl derivatives against ampullary carcinoma

Ampullary carcinoma (AC) is a rare cancer in the world, it is characterized by less attention, fewer models, no in-depth studies, and almost no drug research related to the treatment. Camptothecin (CPT), as the plant anticancer drug, has been the focus of research for a long time. It is a promising strategy to modify and optimize the CPT skeleton to obtain anticancer chemical entities showing low-toxicity and high-efficiency effects. In this study, the site 7 of CPT was modified to obtain a series of CPT derivatives, and their anti-AC activity was evaluated. Among them, compound XSJ110 inhibited the proliferation of DPC-X3 cells (IC50 = 0.133 ± 0.008 μM), which was significantly better than CPT (IC50 = 9.147 ± 0.159 μM). XSJ110 effectively inhibited the proliferation of DPC-X3 cells by inhibition of topoisomerase I (Topo I) activity. XSJ110 arrested cell cycle at G0/G1 phase, induced cell apoptosis, inhibited the proliferation of AC organoids and induced DNA damage. In vivo acute toxicity studies demonstrated that XSJ110 exhibited low toxicity, with no lethality or significant weight loss observed even at high doses. Collectively, these findings indicated that XSJ110 possesses superior activity coupled with favorable safety profiles, which is worthy of further clinical evaluation.

Long-circulating enzyme-activated HSP90-targeted camptothecin derivatives

Drug delivery technology has emerged as an effective strategy to enhance the anti-tumor potential of camptothecins. In this study, we constructed an enzyme-activated targeted drug release system employing a stable valine-alanine linker in combination with a highly cytotoxic camptothecin derivative, AZ'0132. The prodrug, named HC07, was successfully delivered to the tumor site via eHSP90, where it underwent specific cleavage, thereby enhancing its therapeutic window and reducing ocular toxicity. In order to further improve its metabolic properties, we innovatively combined HC07 with plasma endogenous albumin to construct albumin-binding prodrugs HC08 and HC09 for the first time. These prodrugs demonstrated prolonged circulation times in vivo and significantly improved tumor selectivity and anti-tumor efficacy. This work presents a promising eHSP90-based long-circulating drug delivery system, providing new avenues for the design of future anti-cancer drugs.

Uncovering the underlying mechanism of yuanhuacine against colorectal cancer by transcriptomics and experimental investigations

BACKGROUND

Colorectal cancer (CRC) holds the third position in terms of incidence and ranks behind lung cancer in terms of mortality worldwide. Yuanhuacine, one of the main active ingredients of genkwa flos, has demonstrated promising application prospects in the field of cancer treatment. However, its underlying mechanism against CRC has not been fully clarified.

PURPOSE

This study aimed to investigate anti-tumor activity of yuanhuacine and clarify its underlying mechanism in CRC.

METHODS

CRC HCT116, HT-29, Caco-2, SW480, and LS174T cells were used to assess the in vitro anti-tumor activity of yuanhuacine by cell viability, proliferation, apoptosis, cycle distribution, migration, and colony formation assays. Meanwhile, an HT-29 xenograft mouse model was successfully constructed to investigate the anti-tumor effect of yuanhuacine in vivo. Transcriptomic assay and network pharmacology were applied to explore the underlying mechanism of yuanhuacine in combating CRC, which was further verified by quantitative reverse transcription polymerase chain reaction, western blot. The interaction of yuanhuacine with protein was performed by molecular docking, molecular dynamics simulation, and cell thermal shift assays.

RESULTS

Yuanhuacine significantly induced apoptosis and reduced viability of CRC cells with IC50 values ranging from 28.09 to 56.16 μM. Moreover, it suppressed the colony formation ability of CRC cells and inhibited the expression of proliferation marker Ki67 in CRC cells and tissues. Meanwhile, the impairment of cell migration by yuanhuacine has been identified by wound healing assay and transwell migration assay. Furthermore, cell cycle assay showed that yuanhuacine resulted in significant G2/M phase arrest. Yuanhuacine significantly inhibited the tumor growth of HT-29 xenograft mice without obvious pathological changes in major organs. Mechanistically, the differentially expressed genes were enriched in cell cycle by both Kyoto Encyclopedia of Genes and Genomes and Gene Ontology enrichment analyses. The mRNA and protein expressions of PLK1, CCNA2, and TTK were inhibited by yuanhuacine. Cell thermal shift assay further validated the direct interactions between yuanhuacine and each of PLK1, CCNA2, and TTK. The anti-proliferation activity and cell cycle arrest induced by yuanhuacine were reversed by overexpression of PLK1.

CONCLUSIONS

Yuanhuacine is a promising candidate compound in combating CRC by inhibiting proliferation of CRC cells. The major underlying mechanism involves regulating PLK1, which results in G2/M phase arrest.

Plant Alkaloids as Promising Anticancer Compounds with Blood-Brain Barrier Penetration in the Treatment of Glioblastoma: In Vitro and In Vivo Models

Glioblastoma (GBM) is one of the most invasive central nervous system tumors, with rising global incidence. Therapy resistance and poor prognosis highlight the urgent need for new anticancer drugs. Plant alkaloids, a largely unexplored yet promising class of compounds, have previously contributed to oncology treatments. While past reviews provided selective insights, this review aims to collectively compare data from the last decade on (1) plant alkaloid-based anticancer drugs, (2) alkaloid transport across the blood-brain barrier (BBB) in vitro and in vivo, (3) alkaloid mechanisms of action in glioblastoma models (in vitro, in vivo, ex vivo, and in silico), and (4) cytotoxicity and safety profiles. Additionally, innovative drug delivery systems (e.g., nanoparticles and liposomes) are discussed. Focusing on preclinical studies of single plant alkaloids, this review includes 22 botanical families and 28 alkaloids that demonstrated anti-GBM activity. Most alkaloids act in a concentration-dependent manner by (1) reducing glioma cell viability, (2) suppressing proliferation, (3) inhibiting migration and invasion, (4) inducing cell death, (5) downregulating Bcl-2 and key signaling pathways, (6) exhibiting antiangiogenic effects, (7) reducing tumor weight, and (8) improving survival rates. The toxic and adverse effect analysis suggests that alkaloids such as noscapine, lycorine, capsaicin, chelerythrine, caffeine, boldine, and colchicine show favorable therapeutic potential. However, tetrandrine, nitidine, harmine, harmaline, cyclopamine, cocaine, and brucine may pose greater risks than benefits. Piperine's toxicity and berberine's poor bioavailability suggest the need for novel drug formulations. Several alkaloids (kukoamine A, cyclovirobuxine D, α-solanine, oxymatrine, rutaecarpine, and evodiamine) require further pharmacological and toxicological evaluation. Overall, while plant alkaloids show promise in glioblastoma therapy, progress in assessing their BBB penetration remains limited. More comprehensive studies integrating glioma research and advanced drug delivery technologies are needed.

Palladium-Catalyzed Late-Stage Functionalization of Natural Antitumor Drug: Synthesis and Bioactivity of 5-Aryl Camptothecins

Camptothecin (CPT) and its derivatives have garnered significant interest due to their potent anticancer activity. In this study, 62 novel CPT derivatives (1a-31a and 1b-31b) were designed and synthesized through Pd-catalyzed late-stage modification at the C-5 position. The anticancer efficacy of these compounds against three human cancer cell lines was evaluated. Compounds 5R-12a (IC50 = 0.05 ± 0.01 μM against HCT-116) and 5R-6a (IC50 = 0.04 ± 0.03 μM against MCF-7) exhibited enhanced antitumor activity when compared to CPT. The preliminary mechanism of apoptosis was investigated through cell viability assays, protein expression, and docking analysis. The results indicated that compounds 12a and 6a exhibited a greater ability to induce apoptosis and G2/M phase arrest than did CPT. Docking results provided a possible explanation for the superior activity of the 5R configuration. This work would offer new insights for CPT lead compound development.

Exploiting synthetic lethality in PDAC with antibody drug conjugates and ATR inhibition

Pancreatic ductal adenocarcinoma (PDAC) remains a highly lethal malignancy with poor prognosis. Antibody-drug conjugates (ADCs) and their combinations with various anti-tumor drugs have made great progress. Camptothecin, and its derivatives (Dxd, SN-38 or exatecan) targeted TOP1 are effective payloads due to their potent anti-tumor activity. ADCs offer a promising avenue, particularly when integrated with synthetic lethality strategies. In this study, the ADC SA-7-49 is engineered by conjugating exatecan to an anti-TROP2 antibody. The synthetic lethality between camptothecin and the ataxia telangiectasia-mutated and rad3-related (ATR) inhibitors in PDAC cells has been identified through a comprehensive screening of DNA damage response pathways. Drug interactions are quantified using Zero interaction potency (ZIP) scores. RNA sequencing is employed to elucidate the mechanisms driving synergistic effects. ATR inhibitors synergize with camptothecin by inducing apoptosis via ATR-Chk1 pathway inhibition. Knockdown of ATR enhances the sensitivity of PDAC cells to camptothecin and SA-7-49. SA-7-49 selectively targets and eradicates PDAC cells and xenografts without side effects, augmenting anti-tumor activity via synthetic lethality. Our findings reveal a novel therapeutic strategy by integrating ADC technology with synthetic lethality in PDAC.

Spectroscopic and molecular docking studies on binding interactions of camptothecin drugs with bovine serum albumin

This study investigates the binding interactions between bovine serum albumin (BSA) and camptothecin (CPT) drugs (camptothecin, 10-hydroxycamptothecin, topotecan, and irinotecan) using UV-Vis spectroscopy, fluorescence spectroscopy, three-dimensional fluorescence spectroscopy, and molecular docking techniques. The fluorescence quenching of BSA by CPT drugs follows a static mechanism, with binding constants (Kb) ranging from 4.23 × 103 M- 1 (CPT) to 101.30 × 103 M- 1 (irinotecan), demonstrating significant drug binding selectivity. Thermodynamic analysis reveals distinct interaction mechanisms: topotecan binding is driven by hydrogen bonding (ΔH = - 10.96 kJ·mol- 1) and hydrophobic interactions (ΔS = 0.066 kJ·mol- 1·K- 1), while irinotecan exhibits stronger binding dominated by electrostatic forces (ΔH = - 86.77 kJ·mol- 1) with significant entropy loss (ΔS = - 0.161 kJ·mol- 1·K- 1). Molecular docking confirms preferential binding at Sudlow site I of BSA, with hydrophobic interactions and hydrogen bonding as the primary driving forces. These findings provide a comprehensive understanding of CPT-BSA interactions, offering valuable insights for the design of albumin-based drug delivery systems with optimized pharmacokinetic profiles.

Homotypic membrane-camouflaged camptothecin nanorods combining photothermal and chemotherapy for synergistic antitumor therapy

Chemotherapy hardly achieves satisfactory therapeutic efficacy owing to the widely occurred adverse effects and drug tolerance, and the extensively investigated delivery systems suffer from complicated synthesis, low drug loading and less efficient tumor accumulation. Herein, we developed rod-shape nanocrystals to address challenges in the circulation stability, tumor targeting and therapeutic efficacy of camptothecin (CPT), a mainstay of treatments for various cancers. CPT nanorods (CNR) were coated with polydopamine (PDA) to achieve combinational chemo- and photothermal therapies (PTT) and then wrapped with cell membrane (CM) from homotypic tumor cells to obtain CNR@PDA-CM. CNR@PDA-CM retained the membrane proteins presented on 4 T1 cell surface, holding the potential to decrease phagocytic uptake and selectively accumulate in tumor cells. The integration of rod shape and CM wrapping prolongs blood circulation, and CNR@PDA-CM achieves 73-fold longer terminal half-life and nearly 5-fold higher tumor accumulation than free CPT after intravenous injection. When reaching tumor sites, PDA-mediated photothermal effect accelerates CPT release and enhances drug permeability in tumors. The combination of PTT and CPT-based chemotherapy produce robust and synergistic therapeutic outcome in metastatic breast cancer, with almost compete inhibition of tumor growth and 100 % mouse survival at the end of experiment. Thus, this study demonstrates a concise design of CNRs with high drug loading, desirable homotypic targeting, synergistic antitumor efficacy to potentially provide new insight for effective treatment of metastatic cancers.

Design, Synthesis and Bioactive Evaluation of Topo I/c-MYC Dual Inhibitors to Inhibit Oral Cancer via Regulating the PI3K/AKT/NF-κB Signaling Pathway

The significantly rising incidence of oral cancer worldwide urgently requires the identification of novel, effective molecular targets to inhibit the progression of malignancy. DNA topoisomerase I (Topo I) is a well-established target for cancer treatment, and many studies have shown that different cancer cell genes could be targeted more selectively with one type of Topo I inhibitor. In this report, a new scaffold pyridothieno[3,2-c]isoquinoline 11,11-dioxide was designed via the combination of the key fragment or bioisoster of Topo I inhibitor azaindenoisoquinolines and G-quadruplex binder quindoline. Thirty-two target derivatives were synthesized, among which compounds 7be, with potent Topo I inhibition, exhibited effective antiproliferative activity against Cal27, one of the oral cancer cell lines highly expressing Topo I protein. Further studies indicated that 7be could also inhibit the activation of PI3K/AKT/NF-κB pathway and downregulate the level of c-MYC, repress the colony formation and the migration of Cal27 cells and trigger apoptosis and autophagy. Molecular docking indicated that 7be could interact with the complex of Topo I and DNA via a mode similar to the indenoisoquinolines. The results of the Cal27 xenograft model confirmed that 7be exhibited promising anticancer efficacy in vivo, with tumor growth inhibition (TGI) of 64.7% at 20 mg/kg.

Recent advances of selenized tubulin inhibitors in cancer therapy

Cancer treatment always a huge challenge amidst the resistance and relapse caused by the various treatments. Inhibitors targeting mitosis have been considered as promising therapeutic drugs in clinic, of which tubulins play an important role. Selenium (Se) as an essential microelement in humans and animals, playing a crucial role in the formation of anti-oxidase (glutathione peroxidase) and selenoprotein, also attracted broad attention in cancer therapy. Because the introduction of Se atom could change the length and angle of chemical bond and alter their functional properties, regulating selenized chemotherapeutics has become one of the hot spots. However, little attention has been paid to studying the combination of Se and tubulin inhibitors. Herein, we review the latest research results of selenized tubulin inhibitors in cancer therapy, including its mechanisms, categories and biological activities, providing a theoretical basis for different selenized microtubules inhibitors therapies.

Emerging Role of Natural Topoisomerase Inhibitors as Anticancer agents

Topoisomerases I and II are the functionally two forms of DNA topoisomerase. In anticancer research, novel anticancer chemotherapeutical capable of blocking topoisomerase enzymes have been discovered. Most commonly, topoisomerase causes replication fork arrest and doublestrand breaks, and this is how a clinically successful topoisomerase-targeting anticancer medicines work. Unfortunately, this novel mechanism of action has been linked to the development of secondary malignancies as well as cardiotoxicity. The specific binding locations and mechanisms of topoisomerase poisons have been identified by studying the structures of topoisomerase-drug-DNA ternary complexes. Recent breakthroughs in science have revealed that isoform-specific human topoisomerase II poison could be created as safer anticancer drug molecules. It may also be able to develop catalytic inhibitors of topoisomerases by focusing on their inactive conformations. In addition to this, the discovery of new bacterial topoisomerase inhibitor molecules and regulatory proteins could lead to the discovery of new human topoisomerase inhibitors. As a result, biologists, organic chemists, and medicinal chemists worldwide have been identifying, designing, synthesizing, and testing a variety of novel topoisomerase-targeting bioactive compounds. This review focused on topoisomerase inhibitors, their mechanisms of action, and different types of topoisomerase inhibitors that have been developed during the last ten years.

Thiazolidinedione-based structure modification of ergosterol peroxide provides thiazolidinedione-conjugated derivatives as potent agents against breast cancer cells through a PI3K/AKT/mTOR pathway

Ergosterol peroxide (EP) is a steroidal compound isolated from the traditional Chinese medicine Ganoderma lucidum. However, EP is limited by its solubility and moderate potency in antitumor studies. In the present study, a series of novel ergosterol peroxide-3-thiazolidinedione derivatives were designed and synthesized, by changing the linker between ergosterol peroxide and thiazolidinedione, it is expected to obtain compounds with better antitumor activity. The cytotoxicity screening showed that compound 13o is the most active derivative against the MCF-7 cell line with an IC50 of 3.06 μM, and exhibited stronger antitumor activity compared to the parent EP. Further in vitro and vivo studies showed that compound 13o may reduced the mitochondrial membrane potential, increased the reactive oxygen species level and blocked the cell cycle in G0/G1 phase, and induced apoptosis of tumor cells by inhibiting the PI3K/Akt/mTOR pathway. In vivo 4T1 mouse model of breast cancer showed that 13o not only continued to inhibit tumor proliferation but also had a stronger effect than the marketed drug 5-fluorouracil, compound 13o had a good safety profile in vivo. The results suggest that compound 13o may represent a novel, highly potent and low-toxicity structural lead for the development of new breast cancer chemotherapies.

Synthesis and Investigation of Peptide-Drug Conjugates Comprising Camptothecin and a Human Protein-Derived Cell-Penetrating Peptide

Drug targeting strategies, such as peptide-drug conjugates (PDCs), have arisen to combat the issue of off-target toxicity that is commonly associated with chemotherapeutic small molecule drugs. Here we investigated the ability of PDCs comprising a human protein-derived cell-penetrating peptide-platelet factor 4-derived internalization peptide (PDIP)-as a targeting strategy to improve the selectivity of camptothecin (CPT), a topoisomerase I inhibitor that suffers from off-target toxicity. The intranuclear target of CPT allowed exploration of PDC design features required for optimal potency. A suite of PDCs with various structural characteristics, including alternative conjugation strategies (such as azide-alkyne cycloaddition and disulfide conjugation) and linker types (non-cleavable or cleavable), were synthesized and investigated for their anticancer activity. Membrane permeability and cytotoxicity studies revealed that intact PDIP-CPT PDCs can cross membranes, and that PDCs with disulfide- and protease-cleavable linkers liberated free CPT and killed melanoma cells with nanomolar potency. However, selectivity of the PDIP carrier peptide for melanoma compared to noncancerous epidermal cells was not maintained for the PDCs. This study emphasizes the distinct role of the peptide, linker, and drug for optimal PDC activity and highlights the need to carefully match components when assembling PDCs as targeted therapies.

A computer-aided, heterodimer-based "triadic" carrier-free drug delivery platform to mitigate multidrug resistance in lung cancer and enhance efficiency

Co-delivering multiple drugs or circumventing the drug efflux mechanism can significantly decrease multidrug resistance (MDR), a major cause of cancer treatment failure. In this study, we designed and fabricated a universal "three-in-one" self-delivery system for synergistic cancer therapy using a computer-aided strategy. First, we engineered two glutathione (GSH)-responsive heterodimers, ERL-SS-CPT (erlotinib [ERL] linked with camptothecin [CPT] via a disulfide bond [SS]) and CPT-SS-ERI (CPT conjugated with erianin [ERI]), which serve as both cargo and carrier material. Next, molecular dynamics simulations indicated that multiple noncovalent molecular forces, including π-π stacking, hydrogen bonds, hydrophobic interactions, and sulfur bonds, drive the self-assembly process of these heterodimers. We then explored the universality of the heterodimers and developed a "triadic" drug delivery platform comprising 40 variants. Subsequently, we conducted case studies on docetaxel (DTX)-loaded ERL-SS-CPT nanoparticles (denoted as DTX@ERL-SS-CPT NPs) and curcumin (CUR)-loaded ERL-SS-CPT NPs (identified as CUR@CPT-SS-ERI NPs) to comprehensively investigate their self-assembly mechanism, physicochemical properties, storage stability, GSH-responsive drug release, cellular uptake, apoptosis effects, biocompatibility, and cytotoxicity. Both NPs exhibited well-defined spherical structures, high drug loading rates, and excellent storage stability. DTX@ERL-SS-CPT NPs exhibited the strongest cytotoxicity in A549 cells, following the order of DTX@ERL-SS-CPT NPs > ERL-SS-CPT NPs > CPT > DTX > ERL. Conversely, DTX@ERL-SS-CPT NPs showed negligible cytotoxicity in normal human bronchial epithelium cell line (BEAS-2B), indicating good biocompatibility and safety. Similar observations were made for CUR@CPT-SS-ERI NPs regarding biocompatibility and cytotoxicity. Upon endocytosis and encountering intracellular overexpressed GSH, the disulfide-bond linker is cleaved, resulting in the release of the versatile NPs into three parts. The spherical NPs enhance water solubility, reduce the required dosage of free drugs, and increase cellular drug accumulation while suppressing P-glycoprotein (P-gp) expression, leading to apoptosis. This work provides a computer-aided universal strategy-a heterodimer-based "triadic" drug delivery platform-to enhance anticancer efficiency while reducing multidrug resistance.

Drug combinations of camptothecin derivatives promote the antitumor properties

Camptothecin (CPT) derivatives are widely used as small molecule chemotherapeutic agents and have demonstrated efficacy in the treatment of diverse solid tumors. A variety of derivatives have been developed to resolve the drawbacks of poor water solubility, high toxicity and rapid hydrolysis in vivo. However, the obstacles, such as acquired resistance and toxicity, still exist. The utilization of rational drug combinations has the potential to enhance the efficacy and mitigate the toxicity of CPT derivatives. This paper provides an overview of CPT derivatives in combination with other drugs, with a particular focus on cell cycle inhibitors, DNA synthesis inhibitors, anti-metastatic drugs and immunotherapy agents. Concurrently, the mechanisms of antitumor activity of combinations of different classes of drugs and CPT derivatives are elucidated. While the various combination strategies have yielded more favorable therapeutic outcomes, the efficacy and toxicity of the drug combinations are influenced by the inherent properties of the drugs involved. Moreover, a summary of the drug conjugates of CPT derivatives was provided, accompanied by an analysis of the structural activity relationship (SAR). This paves the way for the subsequent developments in drug combinations and delivery modes.

Structurally diverse bufadienolides from the skins of Bufo bufo gargarizans and their cytotoxicity

Natural products, with their extensive chemical diversity, distinctive biological activities, and vast reservoirs, provide a robust foundation for advancing cancer therapeutics. A comprehensive phytochemical investigation of the skins from Bufo bufo gargarizans afforded two new bufadienolide derivatives identified as bufalactamides A and B (1-2), along with six known compounds: argentinogenin (3), desacetylcinobufagin (4), desacetylcinobufaginol (5), cinobufaginol (6), bufalin (7) and gamabufalin (8). The structural elucidation of these compounds was meticulously carried out by analyses of spectroscopic data (1D and 2D NMR, HR-ESIMS), and comparison with the literature data. Plausible biosynthetic pathways for the new compounds were also discussed. Moreover, the cytotoxicity of the compounds was investigated using various cancer cell lines, including lung cancer (A549), colon cancer (HCT-116), liver cancer (SK-Hep-1), and ovarian cancer (SKOV3). Our research findings indicated that compounds 3, and 6-8 exhibit potent cytotoxic activity (IC50 < 2.5 µM). In contrast, compounds 4 and 5 display moderate cytotoxic activity (IC50 < 50 µM) while compounds 1 and 2 show no cytotoxic activity (IC50 > 100 µM). From this data, we conducted a comprehensive analysis of the structure-activity relationships among these compounds.

Nitric oxide-based multi-synergistic nanomedicine: an emerging therapeutic for anticancer

Gas therapy has emerged as a promising approach for treating cancer, with gases like NO, H2S, and CO showing positive effects. Among these, NO is considered a key gas molecule with significant potential in stopping cancer progression. However, due to its high reactivity and short half-life, delivering NO directly to tumors is crucial for enhancing cancer treatment. NO-driven nanomedicines (NONs) have been developed to effectively deliver NO donors to tumors, showing great progress in recent years. This review provides an overview of the latest advancements in NO-based cancer nanotherapeutics. It discusses the types of NO donors used in current research, the mechanisms of action behind NO therapy for cancer, and the different delivery systems for NO donors in nanotherapeutics. It also explores the potential of combining NO donors with other treatments for enhanced cancer therapy. Finally, it examines the future prospects and challenges of using NONs in clinical settings for cancer treatment.

Thiazolidinedione-Conjugated Lupeol Derivatives as Potent Anticancer Agents Through a Mitochondria-Mediated Apoptotic Pathway

To improve the potential of lupeol against cancer cells, a privileged structure, thiazolidinedione, was introduced into its C-3 hydroxy group with ester, piperazine-carbamate, or ethylenediamine as a linker, and three series of thiazolidinedione-conjugated compounds (6a-i, 9a-i, and 12a-i) were prepared. The target compounds were evaluated for their cytotoxic activities against human lung cancer A549, human breast cancer MCF-7, human hepatocarcinoma HepG2, and human hepatic LO2 cell lines, and the results revealed that most of the compounds displayed improved potency over lupeol. Compound 12i exhibited significant activity against the HepG2 cell line, with an IC50 value of 4.40 μM, which is 9.9-fold more potent than lupeol (IC50 = 43.62 μM). Mechanistic studies suggested that 12i could induce HepG2 cell apoptosis, as evidenced by AO/EB staining and annexin V-FITC/propidium iodide dual staining assays. Western blot analysis suggested that compound 12i can upregulate Bax expression, downregulate Bcl-2 expression, and activate the mitochondria-mediated apoptotic pathway. Collectively, compound 12i is worthy of further investigation to support the discovery of effective agents against cancer.

Camptothecin and its derivatives: Advancements, mechanisms and clinical potential in cancer therapy

Camptothecin (CPT), an alkaloid isolated from the Camptotheca tree, has demonstrated significant anticancer properties in a range of malignancies. However, its therapeutic efficacy is limited by its hydrophobicity, poor bioavailability, and systemic toxicity. Derivatives, analogues, and nanoformulations of CPT have been synthesized to overcome these limitations. The aim of this review is to comprehensively analyze existing studies to evaluate the therapeutic efficacy, mechanistic aspects, and clinical potential of CPT and its modified forms, including derivatives, analogues, and nanoformulations, in cancer treatment. A comprehensive literature review was performed using PubMed/Medline, Scopus, and Web of Science databases; articles were selected based on specific inclusion criteria, and data were extracted on the pharmacological profile, clinical studies, and therapeutic efficacy of CPT and its different forms. Current evidence suggests that derivatives and analogues of CPT have improved water solubility, bioavailability, and reduced systemic toxicity compared to CPT. Nanoformulations further enhance targeted delivery and reduce off-target effects. Clinical trials indicate promising outcomes with enhanced survival rates and lower side effects. CPT and its modified forms hold significant promise as potent anticancer agents. Ongoing research and clinical trials are essential for establishing their long-term efficacy and safety; the evidence overwhelmingly supports further development and clinical testing of these compounds.

Aqueous extracts from Dioscorea sansibarensis Pax show cytotoxic and radiosensitizing potential in 3D growing HPV-negative and HPV-positive human head and neck squamous cell carcinoma models

Numerous natural substances have anti-cancer properties. Especially indigenous people use aqueous plant extracts for tea or ointments including Dioscorea sansibarensis Pax to treat various diseases. The aim of this study was to evaluate the cytotoxic and radiosensitizing potential of aqueous extracts from Dioscorea sansibarensis Pax collected from Kenya in a panel of HPV-negative and -positive head and neck squamous cell carcinoma (HNSCC) cells grown in three-dimensional laminin-rich extracellular matrix (3D lrECM). The results show cytotoxicity, radiosensitization and increased levels of residual double strand breaks (DBS) by Dioscorea sansibarensis Pax extracts in HPV-negative and -positive HNSCC models in a concentration- and cell model-dependent manner. Application of ROS scavengers indicated an association between ROS-induced DSB and radiosensitization through Dioscorea sansibarensis Pax pretreatment. High-performance liquid chromatography-tandem mass spectrometry (HPLC-MS/MS) based characterization of Dioscorea sansibarensis Pax identified the main components of the extract including camptothecin. Overall, Dioscorea sansibarensis Pax aqueous extracts alone and in combination with X-ray irradiation showed effective anticancer properties, which are worthy of further mechanistic investigation.

Potent and Selective Oxidatively Labile Ether-Based Prodrugs through Late-Stage Boronate Incorporation

This manuscript describes a new strategy for prodrug synthesis in which a relatively inert ether group is introduced at an early stage in a synthetic sequence and functionalized in the final step to introduce a prodrug-activating group through a chemoselective process. Boryl allyloxy (BAO) ether groups are synthesized through several metal-mediated processes to form entities that are readily cleaved under oxidative conditions commonly found in cancer cells. The high cleavage propensity of the BAO group allows for ether cleavage, making these compounds substantially more hydrolytically stable in comparison to acyl-linked prodrugs while retaining the ability to release alcohols. We report the preparation of prodrug analogues of the natural products camptothecin and pederin from acetal precursors that serve as protecting groups in their synthetic sequences. The BAO acetal groups cleave in the presence of hydrogen peroxide to release the cytotoxic agents. The pederin-based prodrug shows dramatically greater cytotoxicity than negative controls and outstanding selectivity and potency toward cancer cell lines in comparison to non-cancerous cell lines. This late-stage functionalization approach to prodrug synthesis should be applicable to numerous systems that can be accessed through chemoselective processes.

Organo-cation catalyzed enantioselective α-hydroxylation of pyridinone-fused lactones: asymmetric synthesis of SN-38 and irinotecan

A catalytic asymmetric α-hydroxylation of pyridinone-fused lactones, containing the core structure of camptothecin, is described. Development of a novel spiropyrrolidine amide (SPA) derived triazolium bromide organo-cation catalyst is crucial for a highly enantioselective oxidation, which also accommodates a wide array of lactones with various substituents. The resulting tricyclic tertiary alcohol with an oxa-quaternary carbon center can be further applied in the synthesis of SN-38 and irinotecan, two anti-cancer drugs derived from camptothecin.

Natural-source payloads used in the conjugated drugs architecture for cancer therapy: Recent advances and future directions

Drug conjugates are obtained from tumor-located vectors connected to cytotoxic agents via linkers, which are designed to deliver hyper-toxic payloads directly to targeted cancer cells. These drug conjugates include antibody-drug conjugates (ADCs), peptide-drug conjugates (PDCs), small molecule-drug conjugates (SMDCs), nucleic acid aptamer-drug conjugates (ApDCs), and virus-like drug conjugate (VDCs), which show great therapeutic value in the clinic. Drug conjugates consist of a targeting carrier, a linker, and a payload. Payloads are key therapy components. Cytotoxic molecules and their derivatives derived from natural products are commonly used in the payload portion of conjugates. The ideal payload should have sufficient toxicity, stability, coupling sites, and the ability to be released under specific conditions to kill tumor cells. Microtubule protein inhibitors, DNA damage agents, and RNA inhibitors are common cytotoxic molecules. Among these conjugates, cytotoxic molecules of natural origin are summarized based on their mechanism of action, conformational relationships, and the discovery of new derivatives. This paper also mentions some cytotoxic molecules that have the potential to be payloads. It also summarizes the latest technologies and novel conjugates developed in recent years to overcome the shortcomings of ADCs, PDCs, SMDCs, ApDCs, and VDCs. In addition, this paper summarizes the clinical trials conducted on conjugates of these cytotoxic molecules over the last five years. It provides a reference for designing and developing safer and more efficient conjugates.

Design and synthesis of TH19P01-Camptothecin based hybrid peptides inducing effective anticancer responses on sortilin positive cancer cells

Recently, the sortilin receptor (SORT1) was found to be preferentially over-expressed on the surface of many cancer cells, which makes SORT1 a novel anticancer target. The SORT1 binding proprietary peptide TH19P01 could achieve the SORT1-mediated cancer cell binding and subsequent internalization. Inspired by the peptide-drug conjugate (PDC) strategy, the TH19P01-camptothecin (CPT) conjugates were designed, efficiently synthesized, and evaluated for their anticancer potential in this study. The water solubility, in vitro anticancer activity, time-kill kinetics, cellular uptake, anti-migration activity, and hemolysis effects were systematically estimated. Besides, in order to monitor the release of CPT from conjugates in real-time, the CPT/Dnp-based "turn on" hybrid peptide was designed, which indicted that CPT could be sustainably released from the hybrid peptide in both human serum and cancer cellular environments. Strikingly, compared with free CPT, the water solubility, cellular uptake, and selectivity towards cancer cells of hybrid peptide LYJ-2 have all been significantly enhanced. Moreover, unlike free CPT or TH19P01, LYJ-2 exhibited selective anti-proliferative and anti-migration effects against SORT1-positive MDA-MB-231 cells. Collectively, this study not only established efficient strategies to improve the solubility and anticancer potential of chemotherapeutic agent CPT, but also provided important references for the future development of TH19P01 based PDCs targeting SORT1.

The Emerging Role of Natural Products in Cancer Treatment

The exploration of natural products as potential agents for cancer treatment has garnered significant attention in recent years. In this comprehensive review, we delve into the diverse array of natural compounds, including alkaloids, carbohydrates, flavonoids, lignans, polyketides, saponins, tannins, and terpenoids, highlighting their emerging roles in cancer therapy. These compounds, derived from various botanical sources, exhibit a wide range of mechanisms of action, targeting critical pathways involved in cancer progression such as cell proliferation, apoptosis, angiogenesis, and metastasis. Through a meticulous examination of preclinical and clinical studies, we provide insights into the therapeutic potential of these natural products across different cancer types. Furthermore, we discuss the advantages and challenges associated with their use in cancer treatment, emphasizing the need for further research to optimize their efficacy, pharmacokinetics, and delivery methods. Overall, this review underscores the importance of natural products in advancing cancer therapeutics and paves the way for future investigations into their clinical applications.

Stimulus-Responsive Nano-Prodrug Strategies for Cancer Therapy: A Focus on Camptothecin Delivery

Camptothecin (CPT) is a highly cytotoxic molecule with excellent antitumor activity against various cancers. However, its clinical application is severely limited by poor water solubility, easy inactivation, and severe toxicity. Structural modifications and nanoformulations represent two crucial avenues for camptothecin's development. However, the potential for further structural modifications is limited, and camptothecin nanoparticles fabricated via physical loading have the drawbacks of low drug loading and leakage. Prodrug-based CPT nanoformulations have shown unique advantages, including increased drug loading, reduced burst release, improved bioavailability, and minimal toxic side effects. Stimulus-responsive CPT nano-prodrugs that respond to various endogenous or exogenous stimuli by introducing various activatable linkers to achieve spatiotemporally responsive drug release at the tumor site. This review comprehensively summarizes the latest research advances in stimulus-responsive CPT nano-prodrugs, including preparation strategies, responsive release mechanisms, and their applications in cancer therapy. Special focus is placed on the release mechanisms and characteristics of various stimulus-responsive CPT nano-prodrugs and their application in cancer treatment. Furthermore, clinical applications of CPT prodrugs are discussed. Finally, challenges and future research directions for CPT nano-prodrugs are discussed. This review to be valuable to readers engaged in prodrug research is expected.

Two-Phase Electrosynthesis of Dihydroxycoumestans: Discovery of a New Scaffold for Topoisomerase I Poison

Coumestan represents a biologically relevant structural motif distributed in a number of natural products, and the rapid construction of related derivatives as well as the characterization of targets would accelerate lead compound discovery in medicinal chemistry. In this work, a general and scalable approach to 8,9-dihydroxycoumestans via two-electrode constant current electrolysis was developed. The application of a two-phase (aqueous/organic) system plays a crucial role for success, protecting the sensitive o-benzoquinone intermediates from over-oxidation. Based on the structurally diverse products, a primary SAR study on coumestan scaffold was completed, and compound 3 r exhibited potent antiproliferative activities and a robust topoisomerase I (Top1) inhibitory activity. Further mechanism studies demonstrates that compound 3 r was a novel Top1 poison, which might open an avenue for the development of Top1-targeted antitumor agent.

Biological impact and therapeutic potential of a novel camptothecin derivative (FLQY2) in pancreatic cancer through inactivation of the PDK1/AKT/mTOR pathway

BACKGROUND

Camptothecin (CPT), a pentacyclic alkaloid with antitumor properties, is derived from the Camptotheca acuminata. Topotecan and irinotecan (CPT derivatives) were first approved by the Food and Drug Administration for cancer treatment over 25 years ago and remain key anticancer drugs today. However, their use is often limited by clinical toxicity. Despite extensive development efforts, many of these derivatives have not succeeded clinically, particularly in their effectiveness against pancreatic cancer which remains modest.

AIM OF THE STUDY

This study aimed to evaluate the therapeutic activity of FLQY2, a CPT derivative synthesized in our laboratory, against pancreatic cancer, comparing its efficacy and mechanism of action with those of established clinical drugs.

METHODS

The cytotoxic effects of FLQY2 on cancer cells were assessed using an MTT assay. Patient-derived organoid (PDO) models were employed to compare the sensitivity of FLQY2 to existing clinical drugs across various cancers. The impact of FLQY2 on apoptosis and cell cycle arrest in Mia Paca-2 pancreatic cancer cells was examined through flow cytometry. Transcriptomic and proteomic analyses were conducted to explore the underlying mechanisms of FLQY2's antitumor activity. Western blotting was used to determine the levels of proteins regulated by FLQY2. Additionally, the antitumor efficacy of FLQY2 in vivo was evaluated in a pancreatic cancer xenograft model.

RESULTS

FLQY2 demonstrated (1) potent cytotoxicity; (2) superior tumor-suppressive activity in PDO models compared to current clinical drugs such as gemcitabine, 5-fluorouracil, cisplatin, paclitaxel, ivosidenib, infinitinib, and lenvatinib; (3) significantly greater tumor inhibition than paclitaxel liposomes in a pancreatic cancer xenograft model; (4) robust antitumor effects, closely associated with the inhibition of the TOP I and PDK1/AKT/mTOR signaling pathways. In vitro studies revealed that FLQY2 inhibited cell proliferation, colony formation, induced apoptosis, and caused cell cycle arrest at nanomolar concentrations. Furthermore, the combination of FLQY2 and gemcitabine exhibited significant inhibitory and synergistic effects.

CONCLUSION

The study confirmed the involvement of topoisomerase I and the PDK1/AKT/mTOR pathways in mediating the antitumor activity of FLQY2 in treating Mia Paca-2 pancreatic cancer. Therefore, FLQY2 has potential as a novel therapeutic option for patients with pancreatic cancer.

Recognition on pharmacodynamic ingredients of natural products

Natural products (NPs) play an irreplaceable role in the intervention of various diseases and have been considered a critical source of drug development. Many new pharmacodynamic compounds with potential clinical applications have recently been derived from NPs. These compounds range from small molecules to polysaccharides, polypeptides, proteins, self-assembled nanoparticles, and extracellular vesicles. This review summarizes various active substances found in NPs. The investigation of active substances in NPs can potentiate new drug development and promote the in-depth comprehension of the mechanism of action of NPs that can be beneficial in the prevention and treatment of human diseases.

Experimental and computational study on anti-gastric cancer activity and mechanism of evodiamine derivatives

Introduction: Human topoisomerase 1 (TOP1) is an important target of various anticancer compounds. The design and discovery of inhibitors targeting TOP1 are of great significance for the development of anticancer drugs. Evodiamine and thieno [2,3-d] pyridine hybrids show potential antitumor activity. Herein, the anti-gastric cancer activities of these hybrids were investigated. Methods: The inhibitory effects of different concentrations of ten evodiamine derivatives on the gastric cancer cell line SGC-7901 were assessed using a methyl thiazolyl tetrazolium assay. Compounds EVO-1 and EVO-6 strongly inhibited gastric cancer cell proliferation, with inhibition rates of 81.17% ± 5.08% and 80.92% ± 2.75%, respectively. To discover the relationship between the structure and activity of these two derivatives, density functional theory was used to investigate their optimized geometries, natural population charges, frontier molecular orbitals, and molecular electrostatic potentials. To clarify their anti-gastric cancer mechanisms, molecular docking, molecular dynamics simulations, and binding free energy calculations were performed against TOP1. Results: The results demonstrated that these compounds could intercalate into the cleaved DNA-binding site to form a TOP1-DNA-ligand ternary complex, and the ligand remained secure at the cleaved DNA-binding site to form a stable ternary complex. As the binding free energy of compound EVO-1 with TOP1 (-38.33 kcal·mol-1) was lower than that of compound EVO-6 (-33.25 kcal·mol-1), compound EVO-1 could be a more potent anti-gastric cancer agent than compound EVO-6. Discussion: Thus, compound EVO-1 could be a promising anti-gastric cancer drug candidate. This study may facilitate the design and development of novel TOP1 inhibitors.

The development of nanocarriers for natural products

Natural bioactive compounds from plants exhibit substantial pharmacological potency and therapeutic value. However, the development of most plant bioactive compounds is hindered by low solubility and instability. Conventional pharmaceutical forms, such as tablets and capsules, only partially overcome these limitations, restricting their efficacy. With the recent development of nanotechnology, nanocarriers can enhance the bioavailability, stability, and precise intracellular transport of plant bioactive compounds. Researchers are increasingly integrating nanocarrier-based drug delivery systems (NDDS) into the development of natural plant compounds with significant success. Moreover, natural products benefit from nanotechnological enhancement and contribute to the innovation and optimization of nanocarriers via self-assembly, grafting modifications, and biomimetic designs. This review aims to elucidate the collaborative and reciprocal advancement achieved by integrating nanocarriers with botanical products, such as bioactive compounds, polysaccharides, proteins, and extracellular vesicles. This review underscores the salient challenges in nanomedicine, encompassing long-term safety evaluations of nanomedicine formulations, precise targeting mechanisms, biodistribution complexities, and hurdles in clinical translation. Further, this study provides new perspectives to leverage nanotechnology in promoting the development and optimization of natural plant products for nanomedical applications and guiding the progression of NDDS toward enhanced efficiency, precision, and safety. This article is categorized under: Therapeutic Approaches and Drug Discovery > Emerging Technologies Nanotechnology Approaches to Biology > Nanoscale Systems in Biology.

Natural-product-based, carrier-free, noncovalent nanoparticles for tumor chemo-photodynamic combination therapy

Cancer, with its diversity, heterogeneity, and complexity, is a significant contributor to global morbidity, disability, and mortality, highlighting the necessity for transformative treatment approaches. Photodynamic therapy (PDT) has aroused continuous interest as a viable alternative to conventional cancer treatments that encounter drug resistance. Nanotechnology has brought new advances in medicine and has shown great potential in drug delivery and cancer treatment. For precise and efficient therapeutic utilization of such a tumor therapeutic approach with high spatiotemporal selectivity and minimal invasiveness, the carrier-free noncovalent nanoparticles (NPs) based on chemo-photodynamic combination therapy is essential. Utilizing natural products as the foundation for nanodrug development offers unparalleled advantages, including exceptional pharmacological activity, easy functionalization/modification, and well biocompatibility. The natural-product-based, carrier-free, noncovalent NPs revealed excellent synergistic anticancer activity in comparison with free photosensitizers and free bioactive natural products, representing an alternative and favorable combination therapeutic avenue to improve therapeutic efficacy. Herein, a comprehensive summary of current strategies and representative application examples of carrier-free noncovalent NPs in the past decade based on natural products (such as paclitaxel, 10-hydroxycamptothecin, doxorubicin, etoposide, combretastatin A4, epigallocatechin gallate, and curcumin) for tumor chemo-photodynamic combination therapy. We highlight the insightful design and synthesis of the smart carrier-free NPs that aim to enhance PDT efficacy. Meanwhile, we discuss the future challenges and potential opportunities associated with these NPs to provide new enlightenment, spur innovative ideas, and facilitate PDT-mediated clinical transformation.

Chemical Constituents and Their Bioactivities of Plants from the Genus Eupatorium (2015-Present)

The genus Eupatorium belongs to the Asteraceae (Compositae) family and has multiple properties, such as invasiveness and toxicity, and is used in folk medicine. The last review on the chemical constituents of this genus and their biological activities was published in 2015. The present review provides an overview of 192 natural products discovered from 2015 to the present. These products include 63 sesquiterpenoids, 53 benzofuran derivatives, 39 thymol derivatives, 15 fatty acids, 7 diterpenoids, 5 monoterpenoids, 4 acetophenones, and 6 other compounds. We also characterized their respective chemical structures and cytotoxic, antifungal, insecticidal, antibacterial, anti-inflammatory, and antinociceptive activities.

Design, synthesis and cytotoxic activity of molecular hybrids based on quinolin-8-yloxy and cinnamide hybrids and their apoptosis inducing property

The present work aims at design and synthesis of a congeneric series of small hybrids 5 and 6a-i featuring the privileged quinoline scaffold tethered with 2-(arylamido)cinnamide moiety as potential anticancer tubulin polymerization inhibitors. Most of the synthesized hybrids 5 and 6a-i significantly inhibited the growth of the HepG2 cell line, with IC50 ranged from 2.46 to 41.31 μM. In particular, 2-(3,4,5-trimethoxybenzamido)-4-methoxycinnamide-quinoline hybrid 6e displayed potent IC50 value toward the examined cell line, and hence chosen for further mechanistic investigations. It is noteworthy that the antiproliferative action of compound 6e highly correlated well with its ability to inhibit tubulin polymerization. In addition, the most potent hybrid 6e demonstrated a significant modification in the cellular cycle distribution, in addition to provoke of apoptotic death within the tested HepG2 cell line. Furthermore, the mechanistic approach was confirmed by a substantial upregulation in the quantity of active caspase 9 by 5.81-fold relative to untreated control cells.

Unleashing the Potential of Camptothecin: Exploring Innovative Strategies for Structural Modification and Therapeutic Advancements

Camptothecin (CPT) is a potent anti-cancer agent targeting topoisomerase I (TOP1). However, CPT has poor pharmacokinetic properties, causes toxicities, and leads to drug resistance, which limit its clinical use. In this paper, to review the current state of CPT research. We first briefly explain CPT's TOP1 inhibition mechanism and the key hurdles in CPT drug development. Then we examine strategies to overcome CPT's limitations through structural modifications and advanced delivery systems. Though modifications alone seem insufficient to fully enhance CPT's therapeutic potential, structure-activity relationship analysis provides insights to guide optimization of CPT analogs. In comparison, advanced delivery systems integrating controlled release, imaging capabilities, and combination therapies via stimulus-responsive linkers and targeting moieties show great promise for improving CPT's pharmacological profile. Looking forward, multifaceted approaches combining selective CPT derivatives with advanced delivery systems, informed by emerging biological insights, hold promise for fully unleashing CPT's anti-cancer potential.

Three Rounds of Stability-Guided Optimization and Systematical Evaluation of Oncolytic Peptide LTX-315

Oncolytic peptides represent promising novel candidates for anticancer treatments. In our efforts to develop oncolytic peptides possessing both high protease stability and durable anticancer efficiency, three rounds of optimization were conducted on the first-in-class oncolytic peptide LTX-315. The robust synthetic method, in vitro and in vivo anticancer activity, and anticancer mechanism were investigated. The D-type peptides represented by FXY-12 possessed significantly improved proteolytic stability and sustained anticancer efficiency. Strikingly, the novel hybrid peptide FXY-30, containing one FXY-12 and two camptothecin moieties, exhibited the most potent in vitro and in vivo anticancer activities. The mechanism explorations indicated that FXY-30 exhibited rapid membranolytic effects and induced severe DNA double-strand breaks to trigger cell apoptosis. Collectively, this study not only established robust strategies to improve the stability and anticancer potential of oncolytic peptides but also provided valuable references for the future development of D-type peptides-based hybrid anticancer chemotherapeutics.

Progress in approved drugs from natural product resources

Natural products (NPs) have consistently played a pivotal role in pharmaceutical research, exerting profound impacts on the treatment of human diseases. A significant proportion of approved molecular entity drugs are either directly derived from NPs or indirectly through modifications of NPs. This review presents an overview of NP drugs recently approved in China, the United States, and other countries, spanning various disease categories, including cancers, cardiovascular and cerebrovascular diseases, central nervous system disorders, and infectious diseases. The article provides a succinct introduction to the origin, activity, development process, approval details, and mechanism of action of these NP drugs.

Natural products targeting macroautophagy signaling in hepatocellular carcinoma therapy: Recent evidence and perspectives

Hepatocellular carcinoma (HCC), presently the second leading cause of global cancer-related mortality, continues to pose significant challenges in the realm of medical oncology, impacting both clinical drug selection and mechanistic research. Recent investigations have unveiled autophagy-related signaling as a promising avenue for HCC treatment. A growing body of research has highlighted the pivotal role of autophagy-modulating natural products in inhibiting HCC progression. In this context, we provide a concise overview of the fundamental autophagy mechanism and delineate the involvement of autophagic signaling pathways in HCC development. Additionally, we review pertinent studies demonstrating how natural products regulate autophagy to mitigate HCC. Our findings indicate that natural products exhibit cytotoxic effects through the induction of excessive autophagy, simultaneously impeding HCC cell proliferation by autophagy inhibition, thereby depriving HCC cells of essential energy. These effects have been associated with various signaling pathways, including PI3K/AKT, MAPK, AMPK, Wnt/β-catenin, Beclin-1, and ferroautophagy. These results underscore the considerable therapeutic potential of natural products in HCC treatment. However, it is important to note that the present study did not establish definitive thresholds for autophagy induction or inhibition by natural products. Further research in this domain is imperative to gain comprehensive insights into the dual role of autophagy, equipping us with a better understanding of this double-edged sword in HCC management.

First record of the genus Camptotheca (Nyssaceae) in Vietnam and the lectotypification of C.acuminata

As a primary source of anticancer camptothecin, Camptotheca (Nyssaceae) is an economically valuable genus and has long been recorded as endemic to China. Here, Camptotheca is reported as a new record to the flora of Vietnam with the discovery of a wild population of C.acuminata from Lai Chau Province of northern Vietnam. Based on the consultation of relevant literature and type specimens of C.acuminata, a lectotype of the species is designated. Photographic illustrations, morphological description and a distribution map of C.acuminata is provided, and a key to all known species of Nyssaceae in Vietnam is presented, too.

Molecular Hybridization of Alkaloids Using 1,2,3-Triazole-Based Click Chemistry

Alkaloids found in multiple species, known as 'driver species', are more likely to be included in early-stage drug development due to their high biodiversity compared to rare alkaloids. Many synthetic approaches have been employed to hybridize the natural alkaloids in drug development. Click chemistry is a highly efficient and versatile reaction targeting specific areas, making it a valuable tool for creating complex natural products and diverse molecular structures. It has been used to create hybrid alkaloids that address their limitations and serve as potential drugs that mimic natural products. In this review, we highlight the recent advancements made in modifying alkaloids using click chemistry and their potential medicinal applications. We discuss the significance, current trends, and prospects of click chemistry in natural product-based medicine. Furthermore, we have employed computational methods to evaluate the ADMET properties and drug-like qualities of hybrid molecules.

Recent developments on microwave-assisted organic synthesis of nitrogen- and oxygen-containing preferred heterocyclic scaffolds

In recent decades, the utilization of microwave energy has experienced an extraordinary surge, leading to the introduction of innovative and revolutionary applications across various fields of chemistry such as medicinal chemistry, materials science, organic synthesis and heterocyclic chemistry. Herein, we provide a comprehensive literature review on the microwave-assisted organic synthesis of selected heterocycles. We highlight the use of microwave irradiation as an effective method for constructing a diverse range of molecules with high yield and selectivity. We also emphasize the impact of microwave irradiation on the efficient synthesis of N- and O-containing heterocycles that possess bioactive properties, such as anti-cancer, anti-proliferative, and anti-tumor activities. Specific attention is given to the efficient synthesis of pyrazolopyrimidines-, coumarin-, quinoline-, and isatin-based scaffolds, which have been extensively studied for their potential in drug discovery. The article provides valuable insights into the recent synthetic protocols and trends for the development of new drugs using heterocyclic molecules.

A Route for Investigating Psoriasis: From the Perspective of the Pathological Mechanisms and Therapeutic Strategies of Cancer

Psoriasis is an incurable skin disease that develops in about two-thirds of patients before the age of 40 and requires lifelong treatment; its pathological mechanisms have not been fully elucidated. The core pathological process of psoriasis is epidermal thickening caused by the excessive proliferation of epidermal keratinocytes, which is similar to the key feature of cancer; the malignant proliferation of cancer cells causes tumor enlargement, suggesting that there is a certain degree of commonality between psoriasis and cancer. This article reviews the pathological mechanisms that are common to psoriasis and cancer, including the interaction between cell proliferation and an abnormal immune microenvironment, metabolic reprogramming, and epigenetic reprogramming. In addition, there are common therapeutic agents and drug targets between psoriasis and cancer. Thus, psoriasis and cancer share a common pathological mechanisms-drug targets-therapeutic agents framework. On this basis, it is proposed that investigating psoriasis from a cancer perspective is beneficial to enriching the research strategies related to psoriasis.