A novel proteasome inhibitor acting in mitochondrial dysfunction, ER stress and ROS production

In cancer-treatment, potentially therapeutic drugs trigger their effects through apoptotic mechanisms. Generally, cell response is manifested by Bcl-2 family protein regulation, the impairment of mitochondrial functions, and ROS production. Notwithstanding, several drugs operate through proteasome inhibition, which, by inducing the accumulation and aggregation of misfolded or unfolded proteins, can lead to endoplasmic reticulum (ER) stress. Accordingly, it was shown that Amblyomin-X, a Kunitz-type inhibitor identified in the transcriptome of the Amblyomma cajennense tick by ESTs sequence analysis of a cDNA library, obtained in recombinant protein form, induces apoptosis in murine renal adenocarcinoma (RENCA) cells by: inducing imbalance between pro- and anti-apoptotic Bcl-2 family proteins, dysfunction/mitochondrial damage, production of reactive oxygen species (ROS), caspase cascade activation, and proteasome inhibition, all ER-stress inductive. Moreover, there was no manifest action on normal mouse-fibroblast cells (NHI3T3), suggesting an Amblyomin-X tumor-cell selectivity. Taken together, these evidences indicate that Amblyomin-X could be a promising candidate for cancer therapy.Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)Uniao Quimica Farmaceutica NacionalConselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)Inst Butantan, Lab Bioquim & Biofis, BR-05503900 São Paulo, BrazilUniversidade Federal de São Paulo, Dept Bioquim, São Paulo, BrazilInst Butantan, Programa Posgrad Interunidades Biotecnol, USP, IPT, BR-05503900 São Paulo, BrazilUniv São Paulo, Fac Med, Lab Oncol Expt LIM24, São Paulo, BrazilUniversidade Federal de São Paulo, Dept Bioquim, São Paulo, BrazilFAPESP: FAPESP 2010/52669-3FAPESP: CAT/CEPID - 1998/14307-9Web of Scienc

Amblyomin-X induces ER stress, mitochondrial dysfunction, and caspase activation in human melanoma and pancreatic tumor cell

During the last two decades, new insights into proteasome function and its role in several human diseases made it a potential therapeutic target. In this context, Amblyomin-X is a Kunitz-type FXa inhibitor similar to endogenous tissue factor pathway inhibitor (TFPI) and is a novel proteasome inhibitor. Herein, we have demonstrated Amblyomin-X cytotoxicity to different tumor cells lines such as pancreatic (Panc1, AsPC1BxPC3) and melanoma (SK-MEL-5 and SK-MEL-28). Of note, Amblyomin-X was not cytotoxic to normal human fibroblast cells. In addition, Amblyomin-X promoted accumulation of ER stress markers (GRP78 and GADD153) in sensitive (SK-MEL-28) and bortezomib-resistant (Mia-PaCa-2) tumor cells. The intracellular calcium concentration [Ca2+] (i) was slightly modulated in human tumor cells (SK-MEL-28 and Mia-PaCa-2) after 24 h of Amblyomin-X treatment. Furthermore, Amblyomin-X induced mitochondrial dysfunction, cytochrome-c release, PARP cleavage, and activation of caspase cascade in both human tumor (SK-MEL-28 and Mia-PaCa-2) cells. These investigations might help in further understanding of the antitumor properties of Amblyomin-X.Sao Paulo Research Foundation (FAPESP)National Council of Technological and Scientific Development (CNPq, INCTTox)Coordination of Improvement of Higher Education Personnel (CAPES)Uniao Quimica Farmaceutica NacionalButantan Inst, Biochem & Biophys Lab, Ave Vital Brazil 1500, BR-05503900 Sao Paulo, SP, BrazilUniv Fed Sao Paulo, Dept Biochem, Sao Paulo, SP, BrazilUniv Sao Paulo, Inst Chem, Dept Biochem, Sao Paulo, BrazilUniv Sao Paulo, Sch Med, Expt Oncol Med Invest Lab, LIM 24, Sao Paulo, SP, BrazilUniv Fed Sao Paulo, Dept Biochem, Sao Paulo, SP, BrazilFAPESP: 2010/52669-3FAPESP: 2010/07958-7FAPESP: 2011/05969-4FAPESP: CAT/CEPID 1998/14307-9FAPESP: CETICs 2013/07467-1Web of Scienc

Cracking the Code:Enhancing Molecular Tools for Progress in Nanobiotechnology

Nature continually refines its processes for optimal efficiency, especially within biological systems. This article explores the collaborative efforts of researchers worldwide, aiming to mimic nature’s efficiency by developing smarter and more effective nanoscale technologies and biomaterials. Recent advancements highlight progress and prospects in leveraging engineered nucleic acids and proteins for specific tasks, drawing inspiration from natural functions. The focus is developing improved methods for characterizing, understanding, and reprogramming these materials to perform user-defined functions, including personalized therapeutics, targeted drug delivery approaches, engineered scaffolds, and reconfigurable nanodevices. Contributions from academia, government agencies, biotech, and medical settings offer diverse perspectives, promising a comprehensive approach to broad nanobiotechnology objectives. Encompassing topics from mRNA vaccine design to programmable protein-based nanocomputing agents, this work provides insightful perspectives on the trajectory of nanobiotechnology toward a future of enhanced biomimicry and technological innovation.</p

Cracking the Code:Enhancing Molecular Tools for Progress in Nanobiotechnology

Nature continually refines its processes for optimal efficiency, especially within biological systems. This article explores the collaborative efforts of researchers worldwide, aiming to mimic nature’s efficiency by developing smarter and more effective nanoscale technologies and biomaterials. Recent advancements highlight progress and prospects in leveraging engineered nucleic acids and proteins for specific tasks, drawing inspiration from natural functions. The focus is developing improved methods for characterizing, understanding, and reprogramming these materials to perform user-defined functions, including personalized therapeutics, targeted drug delivery approaches, engineered scaffolds, and reconfigurable nanodevices. Contributions from academia, government agencies, biotech, and medical settings offer diverse perspectives, promising a comprehensive approach to broad nanobiotechnology objectives. Encompassing topics from mRNA vaccine design to programmable protein-based nanocomputing agents, this work provides insightful perspectives on the trajectory of nanobiotechnology toward a future of enhanced biomimicry and technological innovation.</p

Amblyomin-X induces ER stress, mitochondrial dysfunction, and caspase activation in human melanoma and pancreatic tumor cell

During the last two decades, new insights into proteasome function and its role in several human diseases made it a potential therapeutic target. In this context, Amblyomin-X is a Kunitz-type FXa inhibitor similar to endogenous tissue factor pathway inhibitor (TFPI) and is a novel proteasome inhibitor. Herein, we have demonstrated Amblyomin-X cytotoxicity to different tumor cells lines such as pancreatic (Panc1, AsPC1BxPC3) and melanoma (SK-MEL-5 and SK-MEL-28). Of note, Amblyomin-X was not cytotoxic to normal human fibroblast cells. In addition, Amblyomin-X promoted accumulation of ER stress markers (GRP78 and GADD153) in sensitive (SK-MEL-28) and bortezomib-resistant (Mia-PaCa-2) tumor cells. The intracellular calcium concentration [Ca(2+)](i) was slightly modulated in human tumor cells (SK-MEL-28 and Mia-PaCa-2) after 24 h of Amblyomin-X treatment. Furthermore, Amblyomin-X induced mitochondrial dysfunction, cytochrome-c release, PARP cleavage, and activation of caspase cascade in both human tumor (SK-MEL-28 and Mia-PaCa-2) cells. These investigations might help in further understanding of the antitumor properties of Amblyomin-X

ATLANTIC EPIPHYTES: a data set of vascular and non-vascular epiphyte plants and lichens from the Atlantic Forest

Epiphytes are hyper-diverse and one of the frequently undervalued life forms in plant surveys and biodiversity inventories. Epiphytes of the Atlantic Forest, one of the most endangered ecosystems in the world, have high endemism and radiated recently in the Pliocene. We aimed to (1) compile an extensive Atlantic Forest data set on vascular, non-vascular plants (including hemiepiphytes), and lichen epiphyte species occurrence and abundance; (2) describe the epiphyte distribution in the Atlantic Forest, in order to indicate future sampling efforts. Our work presents the first epiphyte data set with information on abundance and occurrence of epiphyte phorophyte species. All data compiled here come from three main sources provided by the authors: published sources (comprising peer-reviewed articles, books, and theses), unpublished data, and herbarium data. We compiled a data set composed of 2,095 species, from 89,270 holo/hemiepiphyte records, in the Atlantic Forest of Brazil, Argentina, Paraguay, and Uruguay, recorded from 1824 to early 2018. Most of the records were from qualitative data (occurrence only, 88%), well distributed throughout the Atlantic Forest. For quantitative records, the most common sampling method was individual trees (71%), followed by plot sampling (19%), and transect sampling (10%). Angiosperms (81%) were the most frequently registered group, and Bromeliaceae and Orchidaceae were the families with the greatest number of records (27,272 and 21,945, respectively). Ferns and Lycophytes presented fewer records than Angiosperms, and Polypodiaceae were the most recorded family, and more concentrated in the Southern and Southeastern regions. Data on non-vascular plants and lichens were scarce, with a few disjunct records concentrated in the Northeastern region of the Atlantic Forest. For all non-vascular plant records, Lejeuneaceae, a family of liverworts, was the most recorded family. We hope that our effort to organize scattered epiphyte data help advance the knowledge of epiphyte ecology, as well as our understanding of macroecological and biogeographical patterns in the Atlantic Forest. No copyright restrictions are associated with the data set. Please cite this Ecology Data Paper if the data are used in publication and teaching events. © 2019 The Authors. Ecology © 2019 The Ecological Society of Americ

Endoplasmic reticulum stress induction as a melanoma cell chemosensitization strategy

de tumorigênese em melanomas, ainda não há tratamento eficaz para melanomas metastáticos. Esta ineficácia terapêutica pode estar relacionada com a adaptação e seleção de células de melanoma à indução de estresse de RE. Ultrapassar os níveis sustentados de estresse de RE, interferindo nas vias de adaptação a este estresse, foi o alvo deste estudo na tentativa de propor uma nova estratégia terapêutica para sensibilizar células de melanoma a morte induzida por cisplatina. Mostramos que GADD153, um dos componentes da via de UPR (Unfolded Protein Response) responsável por induzir apoptose em reposta ao estresse de RE, está excluída do núcleo em melanomas primários, metástases ganglionares e viscerais. Este dado sugere que a localização citoplasmática do fator de transcrição GADD153 possa estar envolvida na resposta adaptativa de melanomas ao estresse de RE, uma vez que se sabe que GADD153 se acumula no núcleo em resposta a este estresse. Investigamos se a indução de estresse de RE seria capaz de induzir a translocação de GADD153 para o núcleo e resultar na sensibilização de células de melanoma a morte induzida por cisplatina (CDDP). Realizamos o tratamento de células de melanoma (SbCl2, Mel85, SK-MEL- 29, SK-MEL-28 e SK-MEL-147) com tunicamicina (Tuni), indutor clássico de estresse de RE, previamente ao tratamento com CDDP. Demonstramos que em todas as linhagens exceto em SK-MEL-29, houve um aumento na porcentagem de células hipodiploides (>50%) no tratamento combinado (Tuni>CDDP) comparado ao tratamento com CDDP. As células SK-MEL-147 se mostraram mais sensíveis à indução de estresse de RE e as células SK-MEL-29 mais resistentes. Algumas diferenças entre estas linhagens como a expressão de GRP78 de superfície e presença de oligossacarídeos ?1-6 ligados de superfície podem estar relacionadas com esta resposta diferencial ao estresse de RE. Em todas as linhagens verificamos a acúmulo dos marcadores de UPR, GRP78 e GADD153, após o tratamento com tunicamicina. Além disso, GADD153 foi direcionada para o núcleo em reposta ao tratamento com tunicamicina. O acúmulo de vacúolos acídicos, da proteína autofágica LC3-II e de ROS após o tratamento com Tuni>CDDP, sugerem que tanto a autofagia quanto o estresse oxidativo parecem estar envolvidos na resposta de sensibilização. A inibição de autofagia com cloroquina aumentou a morte induzida por Tuni>CDDP, sugerindo que autofagia desempenha função protetora neste esquema terapêutico. Testamos um segundo agente genotóxico, temozolomida (TMZ), uma droga equivalente à dacarbazina, e a mesma capacidade de sensibilização foi observada pelo prévio tratamento com tunicamicina. A validação deste conceito in vivo foi dificultada pela acentuada toxicidade apresentada por tunicamicina. Avaliamos alguns candidatos a agentes estressores do RE que poderiam apresentar menor toxicidade celular, como swainsonina, atorvastatina, metformina e o composto de cobre [Cu2(apyhist)2(dpam)](ClO4)4. No entanto, não obtivemos resultados promissores com nenhum destes candidatos. Estes resultados mostram que as células tumorais podem ser pré-condicionadas à morte celular se expostas a um prévio estressor de RE, como Tuni, o que leva ao comprometimento da resposta adaptativa a indutores de morte celular como CDDP e TMZ. No entanto, ainda é necessário o estudo de agentes indutores de estresse de RE pouco tóxicos para que esta estratégia terapêutica possa ser utilizada em pacientes com melanomaMelanoma is among the most aggressive malignancies with increasing worldwide incidence and there is no effective treatment for the metastatic disease. The absence of an effective therapy may be due to adaptation and selection of melanoma cells to endoplasmic reticulum (ER) stress. We showed that GADD153, one of the components of the ER stress-mediated apoptosis pathway, was mostly excluded from the nucleus of primary and metastatic melanoma cells compared to nevus cells. These data suggest that the unexpected GADD153 cellular localization could be involved in melanoma cell adaption to ER stress, since GADD153 accumulates in the nucleus during ER stress. Unfolded protein response (UPR) signaling induced in response to ER stress, is a dual process that induces a protective response to restore ER homeostasis or cell death if ER stress is severe or persistent. We investigated if induction of ER stress was a potential strategy to chemosensitize melanoma cells to a second insult by surpassing the adaptive levels to ER stress. We first treated human melanoma cells (SbCl2, SK-MEL-28, Mel85, SK-MEL-29 and SK-MEL-147) with tunicamycin (Tuni), an ER stress inducer, before cisplatin (CDDP) treatment. CDDP is a low cost chemotherapeutic drug currently used in Brazil as a second line for melanoma treatment, especially in youngsters. All cell lines, except SK-MEL-29, demonstrated an >50% increase in the percentage of hypodiploid cells with Tuni>CDDP treatment when compared to CDDP only. The same results were obtained with temozolomide (TMZ), equivalent drug to the active form of dacarbazine, the first line of cytotoxic treatment of melanomas. UPR markers, GRP78 and nuclear translocation of GADD153 were induced by Tuni. Differences between SK-MEL-29 and SK-MEL-147 as cell surface GRP78 and ?1-6 oligossacharides can be related with the differential ER stress sensitization observed in these cells. One of the cellular mechanisms that are regulated by ER stress is autophagy. Accordingly, we observed an increase in the acidic vesicular organelles and accumulation of LC3II in response to Tuni>CDDP treatment. Autophagy inhibition with chloroquine increased Tuni>CDDP induced-cell death, suggesting that autophagy plays a protective role in this response. Oxidative stress can be involved in this scenario since we demonstrated an accumulation of reactive oxygen species in response to Tuni>CDDP. Tunicamycin was cytotoxic in vivo and we investigated alternatives to this antibiotic as swainsonine, atorvastatin, metformin and [Cu2(apyhist)2(dpam)](ClO4)4 but we did not observed ER stress induction. These results indicate that tumor cells could be preconditioned to cell death if exposed to a first ER stressor, such as Tuni, which would compromise an effective adaptive response to a cell death inducer, as CDDP and TMZ. This combined approach may be a promising strategy for melanoma therapy but further studies are necessary to find noncytotoxic alternatives to tunicamyci

Emerging targets for combination therapy in melanomas

AbstractCutaneous melanomas are often difficult to treat when diagnosed in advanced stages. Melanoma cells adapt to survive in extreme environmental conditions and are among the tumors with larger genomic instability. Here we discuss some intrinsic and extrinsic mechanisms of resistance of melanoma cells to both conventional and target therapies, such as autophagy, adaptation to endoplasmic reticulum stress, metabolic reprogramming, mechanisms of tumor repopulation and the role of extracellular vesicles in this later phenomenon. These biological processes are potentially targetable and thus provide a platform for research and discovery of new drugs for combination therapy to manage melanoma patient treatment

Accumulation of prohibitin is a common cellular response to different stressing stimuli and protects melanoma cells from ER stress and chemotherapy-induced cell death

Submitted by Manoel Barata ([email protected]) on 2018-02-09T13:56:40Z No. of bitstreams: 1 GodoyAccumulat.pdf: 5278855 bytes, checksum: 33590f06130be809bab59875ad7d7464 (MD5)Approved for entry into archive by Manoel Barata ([email protected]) on 2018-02-26T17:26:07Z (GMT) No. of bitstreams: 1 GodoyAccumulat.pdf: 5278855 bytes, checksum: 33590f06130be809bab59875ad7d7464 (MD5)Made available in DSpace on 2018-02-26T17:26:07Z (GMT). No. of bitstreams: 1 GodoyAccumulat.pdf: 5278855 bytes, checksum: 33590f06130be809bab59875ad7d7464 (MD5) Previous issue date: 2017Faculdade de Medicina da Universidade de São Paulo. Departamento de Radiologia e Oncologia. Centro de Investigação Translacional em Oncologia (LIM24). São Paulo, SP, Brasil. / Instituto do Câncer do Estado de São Paulo. São Paulo, SP, Brasil.Universidade de São Paulo. Faculdade de Medicina de Ribeirão Preto. Departamento de Biologia Celular, Molecular e Bioagentes Patogênicos. Ribeirão Preto, SP, Brasil. / Fundação Oswaldo Cruz. Instituto Carlos Chagas. Curitiba, PR, Brasil. / Fundação Hemocentro de Ribeirão Preto. Centro de Terapia Celular. Ribeirão Preto, SP, Brasil.Universidade de São Paulo. Faculdade de Medicina de Ribeirão Preto. Departamento de Biologia Celular, Molecular e Bioagentes Patogênicos. Ribeirão Preto, SP, Brasil. / Universidade Federal do Rio Grande do Norte. Instituto do Cérebro. Natal, RN, Brasil. / Fundação Hemocentro de Ribeirão Preto. Centro de Terapia Celular. Ribeirão Preto, SP, Brasil.Universidade Federal do Rio Grande do Sul. Departamento de Biologia Molecular e Biotecnologia. Centro de Biotecnologia. Porto Alegre, RS, Brasil.Faculdade de Medicina da Universidade de São Paulo. Departamento de Radiologia e Oncologia. Centro de Investigação Translacional em Oncologia (LIM24). São Paulo, SP, Brasil. / Instituto do Câncer do Estado de São Paulo. São Paulo, SP, Brasil.Faculdade de Medicina da Universidade de São Paulo. Departamento de Radiologia e Oncologia. Centro de Investigação Translacional em Oncologia (LIM24). São Paulo, SP, Brasil. / Instituto do Câncer do Estado de São Paulo. São Paulo, SP, Brasil.Universidade de São Paulo. Faculdade de Medicina de Ribeirão Preto. Departamento de Biologia Celular, Molecular e Bioagentes Patogênicos. Ribeirão Preto, SP, Brasil. / Fundação Hemocentro de Ribeirão Preto. Centro de Terapia Celular. Ribeirão Preto, SP, Brasil.Universidade de São Paulo. Faculdade de Medicina de Ribeirão Preto. Departamento de Biologia Celular, Molecular e Bioagentes Patogênicos. Ribeirão Preto, SP, Brasil. / Fundação Hemocentro de Ribeirão Preto. Centro de Terapia Celular. Ribeirão Preto, SP, Brasil.Faculdade de Medicina da Universidade de São Paulo. Departamento de Radiologia e Oncologia. Centro de Investigação Translacional em Oncologia (LIM24). São Paulo, SP, Brasil. / Instituto do Câncer do Estado de São Paulo. São Paulo, SP, Brasil.Melanoma is responsible for most deaths among skin cancers and conventional and palliative care chemotherapy are limited due to the development of chemoresistance. We used proteomic analysis to identify cellular responses that lead to chemoresistance of human melanoma cell lines to cisplatin. A systems approach to the proteomic data indicated the participation of specific cellular processes such as oxidative phosphorylation, mitochondrial organization and homeostasis, as well as the unfolded protein response (UPR) to be required for the survival of cells treated with cisplatin. Prohibitin (PHB) was among the proteins consistently accumulated, interacting with the functional clusters associated with resistance to cisplatin. We showed PHB accumulated at different levels in melanoma cell lines under stressing stimuli, such as (i) treatment with temozolomide (TMZ), dacarbazine (DTIC) and cisplatin; (ii) serum deprivation; (iii) tunicamycin, an UPR inducer. Prohibitin accumulated in the mitochondria of melanoma cells after cisplatin and tunicamycin treatment and its de novo accumulation led to chemoresistance melanoma cell lines. In contrast, PHB knock-down sensitized melanoma cells to cisplatin and tunicamycin treatment. We conclude that PHB participates in the survival of cells exposed to different stress stimuli, and can therefore serve as a target for the sensitization of melanoma cells to chemotherapy