Spider venom administration impairs glioblastoma growth and modulates immune response in a non-clinical model

Bonfanti, Amanda Pires; Barreto, Natália Araújo; Munhoz, Jaqueline; Caballero, Marcus; Cordeiro, Gabriel; Silva, Thomaz Augusto Alves da Rocha e; Sutti, Rafael; Moura, Fernanda Messeder; Brunetto, S. Q.; Ramos, Celso Darío; Thomé, Rodolfo; Verinaud, Liana; Rapôso, Catarina

doi:10.1038/s41598-020-62620-9

Cited by 11 publications

(8 citation statements)

References 39 publications

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“…for 14 days induced a reduction or eradication of xenogeneic implanted tumor in mice. The study also showed that the systemic treatment with the venom improved the general condition of the animals, increasing body weight and survival, while did not decrease blood cells, but increased monocytes, indicating the low toxicity of the treatment [28].…”

Section: Discussionmentioning

confidence: 84%

“…Ca 2+ is widely regarded as an important coordinator of these events [39][40][41]. Cell adhesion is another important phenotypic feature during GB progression and is also influenced by Ca 2+ channel activity [28]. The detachment of cells from the primary glioma tumor mass comprises several events involving the destabilization and disorganization of cell-cell adhesion, as well as the loss of expression of neural cell adhesion molecules [42].…”

Section: Discussionmentioning

confidence: 99%

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Spider venom components decrease glioblastoma cell migration and invasion through RhoA-ROCK and Na+/K+-ATPase β2: potential molecular entities to treat invasive brain cancer

et al. 2020

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Background Glioblastoma (GB) cells have the ability to migrate and infiltrate the normal parenchyma, leading to the formation of recurrent tumors often adjacent to the surgical extraction site. We recently showed that Phoneutria nigriventer spider venom (PnV) has anticancer effects mainly on the migration of human GB cell lines (NG97 and U-251). The present work aimed to investigate the effects of isolated components from the venom on migration, invasiveness, morphology and adhesion of GB cells, also evaluating RhoA-ROCK signaling and Na+/K+-ATPase β2 (AMOG) involvement. Methods Human (NG97) GB cells were treated with twelve subfractions (SFs—obtained by HPLC from PnV). Migration and invasion were evaluated by scratch wound healing and transwell assays, respectively. Cell morphology and actin cytoskeleton were shown by GFAP and phalloidin labeling. The assay with fibronectin coated well plate was made to evaluate cell adhesion. Western blotting demonstrated ROCK and AMOG levels and a ROCK inhibitor was used to verify the involvement of this pathway. Values were analyzed by the GraphPad Prism software package and the level of significance was determinate using one-way analysis of variance (ANOVA) followed by Dunnett’s multiple comparisons test. Results Two (SF1 and SF11) of twelve SFs, decreased migration and invasion compared to untreated control cells. Both SFs also altered actin cytoskeleton, changed cell morphology and reduced adhesion. SF1 and SF11 increased ROCK expression and the inhibition of this protein abolished the effects of both subfractions on migration, morphology and adhesion (but not on invasion). SF11 also increased Na+/K+-ATPase β2. Conclusion All components of the venom were evaluated and two SFs were able to impair human glioblastoma cells. The RhoA effector, ROCK, was shown to be involved in the mechanisms of both PnV components. It is possible that AMOG mediates the effect of SF11 on the invasion. Further investigations to isolate and biochemically characterize the molecules are underway.

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Section: Discussionmentioning

confidence: 84%

Section: Discussionmentioning

confidence: 99%

Spider venom components decrease glioblastoma cell migration and invasion through RhoA-ROCK and Na+/K+-ATPase β2: potential molecular entities to treat invasive brain cancer

et al. 2020

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“…As mentioned above, components of the wandering spider ( Phoneutria nigriventer ) venom (PnV), such as PnTx3-6 and PnTx3-3 peptides, have recently been shown to have anti-GB effects ( 49 ). Structurally and functionally uncharacterized peptides isolated from the PnV venom, namely fractions F1, F2, F3 and subfractions SF1–SF11, affected GB cells in vitro ( 56 – 58 ) and impaired GB progression in a xenogeneic mouse model in vivo ( 130 ). However, in this study, PnV venom also affected the TME and especially the local tumor immunosuppressive microenvironment to reactivate anti-tumor immunity, in particular tumor-associated macrophages (TAMs).…”

Section: Molecular Background Of Action Of Venom Peptides On Glioblas...mentioning

confidence: 99%

Bioactive peptides from venoms against glioma progression

et al. 2022

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Venoms are complex mixtures of different molecules and ions. Among them, bioactive peptides have been found to affect cancer hallmarks, such as cell proliferation, cell invasion, cell migration, and can also modulate the immune response of normal and cancer-bearing organisms. In this article, we review the mechanisms of action on these cancer cell features, focusing on bioactive peptides being developed as potential therapeutics for one of the most aggressive and deadly brain tumors, glioblastoma (GB). Novel therapeutic approaches applying bioactive peptides may contribute to multiple targeting of GB and particularly of GB stem cells. Bioactive peptides selectively target cancer cells without harming normal cells. Various molecular targets related to the effects of bioactive peptides on GB have been proposed, including ion channels, integrins, membrane phospholipids and even immunomodulatory treatment of GB. In addition to therapy, some bioactive peptides, such as disintegrins, can also be used for diagnostics or are used as labels for cytotoxic drugs to specifically target cancer cells. Given the limitations described in the last section, successful application in cancer therapy is rather low, as only 3.4% of such peptides have been included in clinical trials and have passed successfully phases I to III. Combined approaches of added bioactive peptides to standard cancer therapies need to be explored using advanced GB in vitro models such as organoids. On the other hand, new methods are also being developed to improve translation from research to practice and provide new hope for GB patients and their families.

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“…It has been shown that biomolecules from scorpion and spider venoms have a chemotherapeutic effect on glioma, neuroblastoma, leukemia, lymphoma, breast cancer, lung cancer, hepatoma, and pancreatic and prostate cancer, among others ( Rapôso, 2017 ). Our group demonstrated that Phoneutria nigriventer spider venom (PnV) decreased cell viability and proliferation, impaired cell cycle and induced apoptosis of human GB lineages ( Barreto dos Santos et al, 2019 ), and reduced or eradicated the development of GB in a preclinical trial developed in mice ( Bonfanti et al, 2020 ), and PnV-isolated components impaired cell migration and adhesion through RhoA-ROCK and Na + /K + -ATPase ( Barreto et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Isolated Components From Spider Venom Targeting Human Glioblastoma Cells and Its Potential Combined Therapy With Rapamycin

Caballero

Barreto

Bonfanti

et al. 2022

Front. Mol. Biosci.

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Glioblastomas (GBs) are responsible for a higher mortality rate among gliomas, corresponding to more than 50% of them and representing a challenge in terms of therapy and prognosis. Peptide-based antineoplastic therapy is a vast and promising field, and these molecules are one of the main classes present in spider venoms. Recently, our research group demonstrated the cytotoxic effects of Phoneutria nigriventer spider venom (PnV) in GBs. The present study aimed to select the purified PnV-components with potential antineoplastic effects, as well as to compare different metabolic conditions. Human GB (NG97) cells were treated with the PnV fractions: F1 (less than 3 kDa), F2 (between 3 and 10 kDa), and F3 (greater than 10 kDa). After treatments, viability (MTT), proliferation (CFSE), death (Annexin V/propidium iodide-PI), and cell cycle (PI) assays were performed. The F1 and F2 fractions in acute periods (1 and 5 h) and low concentrations (0.1 and 1 μg/ml) showed more relevant effects and were repurified in subfractions (SF1–SF11); from these, SF3 and SF4 showed the most significant effects. The previous inhibition of mTOR by rapamycin had a synergistic effect with SFs, reducing cell viability even more significantly than the untreated control. Taken together, the results point to components present in SF3 and SF4 as potential prototypes for the development of new drugs for GB treatment and stimulate studies to use these compounds in combination therapy with a rapamycin-like activity. Future studies will be conducted to characterize, synthesize the molecules, and to evaluate the efficacy and safety in preclinical models.

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Spider venom administration impairs glioblastoma growth and modulates immune response in a non-clinical model

Cited by 11 publications

References 39 publications

Spider venom components decrease glioblastoma cell migration and invasion through RhoA-ROCK and Na+/K+-ATPase β2: potential molecular entities to treat invasive brain cancer

Spider venom components decrease glioblastoma cell migration and invasion through RhoA-ROCK and Na+/K+-ATPase β2: potential molecular entities to treat invasive brain cancer

Bioactive peptides from venoms against glioma progression

Isolated Components From Spider Venom Targeting Human Glioblastoma Cells and Its Potential Combined Therapy With Rapamycin

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