Search Results (62)

Polyploidy in plants can enhance stress resistance and secondary metabolite production, offering potential benefits for Clausena lansium (L.) Skeel, a medicinally valuable species. However, systematic studies of polyploidy-induced morphological, anatomical, and metabolic changes in this species are lacking. This study aimed to induce and characterize polyploid C. lansium lines, assess ploidy-dependent variations, and evaluate their impact on bioactive metabolite accumulation. Three cultivars were hybridized, treated with colchicine, and bred, yielding 13 stable polyploid lines confirmed by flow cytometry and chromosome counting. The polyploids exhibited distinct traits, including larger pollen grains, altered leaf margins, increased leaflet numbers, enlarged guard cells with reduced stomatal density, and thicker leaf tissues. Metabolomic analysis revealed that tetraploids accumulated significantly higher levels of flavonoids, alkaloids, and phenolic acids compared to diploids, while triploids showed moderate increases. These findings demonstrate that polyploidization, particularly tetraploidy, enhances C. lansium’s medicinal potential by boosting pharmacologically active compounds. The study expands germplasm resources and supports the development of high-quality cultivars for pharmaceutical applications. Full article

Mammary tumors are the most common neoplasms diagnosed in female dogs and have been considered excellent models for studying human breast cancer. Establishing cell lines from primary cultures of canine mammary tumors provides an in vitro model to better understand the disease and develop new treatments. This study aimed to establish and characterize canine mammary tumor cell lines. Ten cell cultures were generated from tumor tissue obtained from affected dogs, including seven from primary mammary tumors and three from metastatic sites. Characterization included molecular marker expression (ER, PR, HER2, cytokeratin 5/6 (CK5/6), vimentin, and the marker of cell proliferation Ki67) and in vitro tumorigenic capacity assessment. Additionally, the susceptibility of five cell lines to DOX, 5-FU, paclitaxel, colchicine, and carboplatin was evaluated using the MTT assay. ICC analysis revealed negative expression of hormonal receptors (ER and PR) in five cell lines, while only one cell line was positive for both. Six cell lines were HER2-negative and positive for vimentin. Five cell lines exhibited in vitro tumorigenic capacity, forming colonies in soft agar. DOX showed the highest growth-inhibitory effect (DOX > Paclitaxel > Colchicine > 5-FU > Carboplatin). Two cell lines had a minimal concentration for 50% inhibition in vitro (IC₅₀) < 0.63 µM and 4.37 ± 0.40 µM for DOX, while one was sensitive to colchicine and paclitaxel (IC₅₀ 0.19 µM and 0.04 µM, respectively). All tested cell lines were resistant to carboplatin and 5-FU. These cell lines provide a valuable model for studying breast cancer in humans and dogs and evaluating new potential therapeutic strategies. Full article

Background/Objectives: Leishmaniasis remains a neglected tropical disease, with nearly one million new cases annually and limited investment in research. Current treatments, primarily based on pentavalent antimonials, are associated with severe side effects and increasing resistance. This study aims to develop a novel therapeutic strategy using a nanomaterial functionalized with sialic acid (SA) and colchicine (COL) to selectively target Leishmania braziliensis parasites. Methods: A nanostructured system was engineered by functionalizing its surface with SA and COL. SA was chosen to mimic host cell surfaces, enhancing parasite attraction, while COL was selected for its known leishmanicidal properties. The nanomaterial was designed to concentrate extracellular parasites on its surface via SA-mediated interactions, thereby increasing local COL efficacy. Results: The functionalized nanomaterial demonstrated a dual mechanism: SA facilitated the selective accumulation of Leishmania braziliensis parasites on the nanostructure surface, while COL exerted a cytotoxic effect. This synergistic interaction resulted in enhanced parasite mortality in vitro, suggesting improved selectivity and potency compared to conventional treatments. Conclusions: The proposed nanomaterial offers a promising alternative for leishmaniasis treatment by combining targeted parasite attraction with localized drug delivery. This strategy may reduce systemic toxicity and improve therapeutic outcomes. Full article

Expanding genetic variability of cultivated cotton (Gossypium hirsutum) is essential for improving fiber quality and pest resistance. This study synthesized allotetraploids through interspecific hybridization between G. herbaceum (A₁) and G. nelsonii (G₃). Upon chromosome doubling using 0.2% colchicine, fertile F₁C allotetraploids (A₁A₁G₃G₃) were developed. Cytogenetic analysis confirmed chromosome stability of synthetic allotetraploids, and 74 polymorphic SSR markers verified hybridity and parental contributions. The F₁C hybrids exhibited enhanced resistance to cotton aphids (Aphis gossypii) and whiteflies (Aleyrodidae), with respective infestation rates of 5.2–5.6% and 5.4–5.8%, lower than those of G. hirsutum cv. Ravnak-1 (22.1% and 23.9%). Superior fiber length (25.0–26.0 mm) was observed in complex hybrids and backcross progeny, confirming the potential for trait introgression into elite cultivars. Phylogenetic analysis based on SSR data clearly differentiated G. herbaceum from Australian wild species, demonstrating successful bridging of divergent genomes. The F₁C hybrids consistently expressed dominant G. nelsonii-derived traits regardless of the hybridization direction and clustered phylogenetically closer to the wild parent. These synthetic allotetraploids could broaden the genetic base of G. hirsutum, addressing cultivation constraints through improved biotic stress resilience and fiber quality traits. The study establishes a robust framework for utilizing wild Gossypium species to overcome genetic bottlenecks in conventional cotton breeding programs. Full article

High-risk neuroblastoma remains a clinically challenging pediatric cancer, with an approximate five-year survival rate of ~60%. Frontline therapy for this group of patients includes surgery and intensive chemotherapy that involves combinations of the tubulin inhibitor vincristine with several other chemotherapeutics. Unfortunately, unresponsiveness to therapy and relapse are common, with tumors often displaying resistance to vincristine. Recently, we characterized a novel set of tubulin inhibitors that are distinct from vincristine and bind within the colchicine binding site present on tubulin monomers. Colchicine binding site inhibitors (CBSIs) have gained traction as improved chemotherapeutics due to their potential to overcome tubulin inhibitor-induced resistance. In this study, we investigate the functional impact of CBSI treatment on multiple neuroblastoma cell lines, including those that are vincristine-resistant. We demonstrate that our newly developed compounds are effective at disrupting cell division in non-resistant and resistant cells and have cellular activity against vincristine-resistant cell lines. Interestingly, we find that vincristine-resistant cell lines differ in their ability to undergo apoptotic cell death in response to CBSI treatment. Taken together, these findings provide a solid foundation to further investigate the utility of CBSIs for neuroblastoma treatment, while highlighting the distinct resistance mechanisms that can emerge in these childhood cancers. Full article

Inflammation is a multifaceted biological response of the immune system against various harmful stimuli, including pathogens (such as bacteria and viruses), cellular damage, toxins, and natural/synthetic irritants. This protective mechanism is essential for eliminating the cause of injury, removing damaged cells, and initiating the repair process. While inflammation is a fundamental component of the body’s defense and healing process, its dysregulation can lead to pathological consequences, contributing to various acute and chronic diseases, such as autoimmune disorders, cancer, metabolic syndromes, cardiovascular diseases, neurodegenerative conditions, and other systemic complications. Generally, non-steroidal anti-inflammatory drugs (NSAIDs), corticosteroids, disease-modifying anti-rheumatic drugs (DMARDs), antihistamines, biologics, and colchicine are used as pharmacological agents in the management of inflammatory diseases. However, these conventional treatments often have limitations, including adverse side effects, long-term toxicity, and drug resistance. In contrast, enzyme-based therapeutics have emerged as a promising alternative due to their high specificity, catalytic efficiency, and ability to modulate inflammatory pathways with reduced side effects. These enzymes function by scavenging reactive oxygen species (ROS), inhibiting cytokine transcription, degrading circulating cytokines, and blocking cytokine release by targeting exocytosis-related receptors. Additionally, their role in tissue repair and regeneration further enhances their therapeutic potential. Most natural anti-inflammatory enzymes belong to the oxidoreductase class, including catalase and superoxide dismutase, as well as hydrolases such as trypsin, chymotrypsin, nattokinase, bromelain, papain, serratiopeptidase, collagenase, hyaluronidase, and lysozyme. Engineered enzymes, such as Tobacco Etch Virus (TEV) protease and botulinum neurotoxin type A (BoNT/A), have also demonstrated significant potential in targeted anti-inflammatory therapies. Recent advancements in enzyme engineering, nanotechnology-based enzyme delivery, and biopharmaceutical formulations have further expanded their applicability in treating inflammatory diseases. This review provides a comprehensive overview of both natural and engineered enzymes, along with their formulations, used as anti-inflammatory therapeutics. It highlights improvements in stability, efficacy, and specificity, as well as minimized immunogenicity, while discussing their mechanisms of action and clinical applications and potential future developments in enzyme-based biomedical therapeutics. Full article

Familial Mediterranean Fever (FMF) is characterized by recurrent febrile attacks and serositis. While colchicine is the primary treatment for FMF, some patients present resistance or intolerance with respect to this drug. Anakinra—an IL-1 receptor antagonist—has demonstrated efficacy in colchicine-resistant or -intolerant FMF patients. Background and Objectives: This study aimed to evaluate the clinical characteristics, treatment duration, response to therapy, dose interval modifications, and long-term outcomes in FMF patients treated with anakinra. Materials and Methods: We retrospectively analyzed data from 68 FMF patients who were colchicine-resistant or -intolerant and received anakinra treatment. Results: The median patient age was 40.2 years, with a predominance of female patients (57.3%). The median follow-up duration for patients treated with anakinra was 34.2 months. Anakinra dosing was successfully extended in 30.8% of patients. Eight patients discontinued anakinra due to remission, with a median remission duration of 18.4 months. In a subgroup analysis of 57 patients treated with anakinra for at least 12 months, a significant decrease was observed in Pras scores at 0 months, 3 months, and 12 months, as well as in Erythrocyte Sedimentation Rate, C-reactive protein, and Serum Amyloid A values (all p < 0.001). Statistically significant decreases in 24 h proteinuria values were found between 0 and 3 months, 3 and 12 months, and 0 and 12 months (p = 0.011, p = 0.006, and p = 0.007, respectively). Anakinra use in pregnancy and kidney transplant recipients was well tolerated. Dose extension and treatment discontinuation in remission are feasible strategies. Conclusions: These findings support the use of anakinra as a good treatment option in selected patients. Full article

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. Full article

Familial Mediterranean fever (FMF) is an autoinflammatory genetic disorder characterized by recurrent fevers and inflammation of the serous membranes in the abdomen, lungs, and joints. Currently, the standard treatment of FMF includes colchicine, which is an alkaloid, derived from Colchicum autumnale. Colchicine’s efficacy in FMF is well-established as it is used both to prevent acute attacks and reduce the risk of long-term complications. However, despite these available treatments, 5–10% of patients exhibit resistance to the drug. It has been demonstrated that polymorphisms in several genes involved in inflammation can influence treatment outcomes and the risk of FMF complications like amyloidosis. Among them, some research focused on polymorphism affecting adenosine triphosphate (ATP)-binding cassette sub-family B member 1 (ABCB1) gene encoding for P-glycoprotein. P-glycoprotein is considered a key transporter protein as it regulates the absorption, distribution, and excretion of several drugs, including colchicine. In diseases like FMF, ABCB1 polymorphisms have been shown to affect the response to colchicine, potentially leading to treatment resistance or altered toxicity. Based on this evidence, this systematic review aims to analyze available evidence on ABCB1-mediated colchicine transport and its clinical implications in FMF, showing how relevant ABCB1 variants are in response to therapy. Full article

Background/Objectives: The elimination of bacterial biofilm formation is an effective strategy against bacterial infections. The objective was to design 27 colchicine C-ring modified amine derivatives and evaluate their inhibitory activities against the biofilms of MRSA USA300. Methods: Design 27 colchicine C-ring modified amine derivatives. Evaluate their inhibitory activities against MRSA USA300 biofilms. Conduct antibacterial or synergistic antibacterial experiments. Research the phenotypic mechanisms related to biofilm-related genes icaA and agrA. Results: The experiments showed that most compounds in this series exhibited varying degrees of biofilm inhibitory activity (with inhibition rates ranging from 7.72% to 40.79%). Further verification through antibacterial or synergistic antibacterial experiments revealed that the compounds with biofilm-inhibiting effects (compounds 7b–11b) generally had certain antibacterial activities (MICs = 16–32 μg/mL) or synergistic antibacterial effects (FICIs < 0.5). Furthermore, through in-depth research on their phenotypic mechanisms (i.e., research on biofilm-related mechanisms), it was found that the compounds with antibacterial or synergistic antibacterial properties could inhibit the formation of biofilms by affecting the regulation of the biofilm-related genes icaA and agrA. Conclusions: The designed colchicine C-ring modified amine derivatives showed potential in inhibiting MRSA biofilms, and their antibacterial or synergistic antibacterial properties are related to the regulation of biofilm-related genes icaA and agrA, demonstrating inhibitory activity against MRSA. Full article

Background/Objectives: Studies have shown that some mutations, especially M694V, are correlated with renal RI and/or AA. There are limited data about rare mutations on severity of the disease and RI. Today, evaluating genotype–phenotype correlations in rare mutations is important to better understand FMF. We aimed to evaluate clinical, demographic and genetic changes and genotype–phenotype correlations in pediatric patients with FMF over thirty years as well as the importance of the rare mutations. Methods: A total of 2765 pediatric patients with FMF were included in this study. Genetic results were firstly divided into ten groups including rare mutations. Rare mutations were seen in 2% of all patients and divided into eight groups. Results: There was a significant increase in compound heterozygous mutations, E148Q het/hom, R202Q het/hom, complex mutations and rare mutations in the last decade. RI wo AA was 5.8% and AA was 1% in the patients with rare mutations. While M694V and compound het with M694V were positively correlated with severe PRAS, E148Q and V726A were negatively correlated with severe PRAS (p < 0.05, R = 0.137, R = −0.077, R= −0.05, respectively). Although K695R mutation was negatively correlated with severe PRAS (p < 0.05, R = −0.04), the rate of RI was 20%. Although the rare mutation R761H was negatively correlated with severe PRAS (p < 0.05, R = −0.051), the colchicine resistance rate was 8.3%. Conclusions: It may be misleading for clinicians that mutations which have increased in frequency over the years are clinically mild. RI and AA rates in rare mutations are not less than the related rates in common mutations. Full article

Gastrointestinal nematodes (GINs) inflict significant economic losses on sheep and goat farming globally due to reduced productivity and the development of anthelmintic resistance. Sustainable control strategies are urgently needed including the exploration of medicinal plants as safer alternatives to chemical anthelmintics. This genus of plants is used for anti-inflammatory, antioxidant, and antimicrobial activities. In this study, we aimed to evaluate the anthelmintic activities of Nepeta racemosa Lam. MeOH extract, n-hexane, dichloromethane (DCM), ethyl acetate (EtOAc), n-buthanol (n-BuOH) and aqueous (H₂O) subextracts, and quantify rosmarinic acid in the active extract by the HPLC method, and perform in silico molecular docking studies of rosmarinic acid to examine its binding interactions with tubulin. The anthelmintic activity of the plant extracts on gastrointestinal nematode eggs and larvae (L3) of the sheep was assessed using in vitro test methods such as the egg hatch assay and larval motility assay, conducted over a 24 h period (1, 2, 3, 4, 6, 8, 24). All extracts exhibited 100% effectiveness in the egg hatch inhibition assay, regardless of concentration (50–1.5625 mg/mL). The EtOAc subextract shows the highest effectiveness at 79.66%, followed by the MeOH extract at 74.00%, water at 64.00%, n-hexane at 67.00%, and DCM at 61.00%, and the lowest effectiveness is observed with n-BuOH at 51.66% in the larval motility assay. The major compound of EtOAc extract, the most active extract of N. racemosa, was determined as rosmarinic acid and its amount in the extract was determined as 14.50 mg/100 mg dry extract. The amount of rosmarinic acid in the MeOH extract was found to be 0.21 mg/100 mg dry extract. n-Hexane, DCM, n-BuOH, and H₂O extracts’ rosmarinic acid content was lower than the LOQ value. As tubulin plays an important role in the mechanism of anthelmintics, the major compound of the most active extract (NR-EtOAc) rosmarinic acid was docked onto the colchicine-binding site of the tubulin (5OV7) protein. Rosmarinic acid showed a similar activity spectrum to the anthelmintic drug albendazole. The discovery of low-cost and low-toxicity anthelmintic compounds is very important. Full article

Colchicine is an alkaloid traditionally used to treat inflammatory conditions such as gout and familial Mediterranean fever. Currently, there are proposals for the use of this drug in several other situations, such as cardiovascular and liver diseases and diabetes. In this study, the current literature on the potential of colchicine in the treatment of obesity and metabolic syndrome (MS) was evaluated. The inhibitory action of the NLRP3 inflammasome and other processes, such as reductions in the migration and activation of immune system cells, are effects observed in both in vitro studies and animal models related to colchicine, as well as the promotion of mechanisms of the intensification of lipid metabolism, the reduction of tissue fibrosis, and the reduction of serum glucose and triglycerides. These factors are associated with changes in the prognoses of patients with MS, which, together with obesity, has a high association with inflammatory mechanisms for its maintenance and secondary impairments to homeostasis. In humans, clinical research has rarely addressed the use of colchicine in obesity and MS, with only one pilot randomized clinical trial having been conducted, which identified a beneficial anti-inflammatory effect on endothelial function and the process of insulin resistance in this population. However, it is not yet possible to extrapolate its findings and apply its results to a broader context. Given the potential of this “ancient drug” in various pathological contexts and its good tolerability, it is important that its properties continue to be investigated and that more clinical studies be conducted to expand the therapeutic applications of this low-cost substance in patients with obesity and MS. Full article

Background and Objectives: Familial Mediterranean fever (FMF) is an inherited autoinflammatory disease characterized by recurrent febrile attacks and serosal inflammation. The goals of FMF treatment are to prevent acute attacks and the development of amyloidosis. This study aimed to investigate the benefit of switching to compressed colchicine tablets in patients with FMF who are resistant or intolerant to the pharmaceutical preparation of coated colchicine tablets in terms of attack frequency and side effects. Materials and Methods: Patients who developed resistance and intolerance under coated colchicine tablet treatment and, therefore, switched to compressed colchicine tablets were identified. The attack frequencies and drug-related side effects in patients using the two different pharmaceutical colchicine preparations were compared. Results: The mean age of the 172 patients treated with compressed tablets alone following coated tablets was 36.3 ± 11.4 years, and 75 (43.6%) were male. The most common genetic mutation was detected as M694V in 111 (64.5%) patients, and 36 (20.9%) of them were homozygous. A decrease in the daily colchicine dose was found after switching to compressed colchicine tablets in patients followed for 7 years (2.1 ± 0.7 mg vs. 1.7 ± 0.5 mg; p < 0.001). Episodes lasted for one to three days and then resolved spontaneously. After treatment with the compressed tablet form of colchicine, 129 (75%), 33 (19%), and 10 (6%) patients had 0–3, 4–6, and more than 7 attacks, respectively (p < 0.001). Diarrhea and aminotransferase elevation, the most common side effects in patients using coated colchicine tablets, decreased after using compressed colchicine tablets (p < 0.001). Conclusions: Compressed colchicine tablets were shown to be effective in patients who did not respond to coated colchicine therapy and those with pre-treatment intolerance to biological agents. Full article

Low-grade inflammation (LGI) represents a key driver of type 2 diabetes (T2D) and its associated cardiovascular diseases (CVDs). Indeed, inflammatory markers such as hs-CRP and IL-6 predict the development of T2D and its complications, suggesting that LGI already increases before T2D diagnosis and remains elevated even after treatment. Overnutrition, unhealthy diets, physical inactivity, obesity, and aging are all recognized triggers of LGI, promoting insulin resistance and sustaining the pathogenesis of T2D. Once developed, and even before frank appearance, people with T2D undergo a pathological metabolic remodeling, with an alteration of multiple CVD risk factors, i.e., glycemia, lipids, blood pressure, and renal function. In turn, such variables foster a range of inflammatory pathways and mechanisms, e.g., immune cell stimulation, the accrual of senescent cells, long-lasting epigenetic changes, and trained immunity, which are held to chronically fuel LGI at the systemic and tissue levels. Targeting of CVD risk factors partially ameliorates LGI. However, some long-lasting inflammatory pathways are unaffected by common therapies, and LGI burden is still increased in many T2D patients, a phenomenon possibly underlying the residual inflammatory risk (i.e., having hs-CRP > 2 mg/dL despite optimal LDL cholesterol control). On the other hand, selected disease-modifying drugs, e.g., GLP-1RA, seem to also act on the pathogenesis of T2D, curbing the inflammatory trajectory of the disease and possibly preventing it if introduced early. In addition, selected trials demonstrated the potential of canonical anti-inflammatory therapies in reducing the rate of CVDs in patients with this condition or at high risk for it, many of whom had T2D. Since colchicine, an inhibitor of immune cell activation, is now approved for the prevention of CVDs, it might be worth exploring a possible therapeutic paradigm to identify subjects with T2D and an increased LGI burden to treat them with this drug. Upcoming studies will reveal whether disease-modifying drugs reverse early T2D by suppressing sources of LGI and whether colchicine has a broad benefit in people with this condition. Full article