Research Progress on Mechanism of Action of DHODH in Progression of Malignant Tumors / 肿瘤防治研究

Dihydroorotate dehydrogenase (DHODH) is a flavin-dependent metabolic enzyme that oxidizes dihydroorotate acid to orotic acid in the de novo synthesis pathway of pyrimidine metabolism. DHODH is located in mitochondria, closely related to cellular oxidative phosphorylation, and an important suppressor of the ferroptosis pathway. This study investigates the influence of DHODH on the progression of malignant tumors, including its important role in the de novo synthesis of pyrimidine, oxidative phosphorylation, and ferroptosis. The objective is to present evidence that DHODH is a potential target for the clinical treatment of tumors.

Exposure to Electromagnetic Fields from Mobile Phones and Fructose consumption Coalesce to Perturb Metabolic Regulators AMPK/SIRT1-UCP2/FOXO1 in Growing Rats / 生物医学与环境科学（英文）

OBJECTIVE@#In this study, the combined effect of two stressors, namely, electromagnetic fields (EMFs) from mobile phones and fructose consumption, on hypothalamic and hepatic master metabolic regulators of the AMPK/SIRT1-UCP2/FOXO1 pathway were elucidated to delineate the underlying molecular mechanisms of insulin resistance.@*METHODS@#Weaned Wistar rats (28 days old) were divided into 4 groups: Normal, Exposure Only (ExpO), Fructose Only (FruO), and Exposure and Fructose (EF). Each group was provided standard laboratory chow ad libitum for 8 weeks . Additionally, the control groups, namely, the Normal and FruO groups, had unrestricted access to drinking water and fructose solution (15%), respectively. Furthermore, the respective treatment groups, namely, the ExpO and EF groups, received EMF exposure (1,760 MHz, 2 h/day x 8 weeks). In early adulthood, mitochondrial function, insulin receptor signaling, and oxidative stress signals in hypothalamic and hepatic tissues were assessed using western blotting and biochemical analysis.@*RESULT@#In the hypothalamic tissue of EF, SIRT1, FOXO 1, p-PI3K, p-AKT, Complex III, UCP2, MnSOD, and catalase expressions and OXPHOS and GSH activities were significantly decreased ( P < 0.05) compared to the Normal, ExpO, and FruO groups. In hepatic tissue of EF, the p-AMPKα, SIRT1, FOXO1, IRS1, p-PI3K, Complex I, II, III, IV, V, UCP2, and MnSOD expressions and the activity of OXPHOS, SOD, catalase, and GSH were significantly reduced compared to the Normal group ( P < 0.05).@*CONCLUSION@#The findings suggest that the combination of EMF exposure and fructose consumption during childhood and adolescence in Wistar rats disrupts the closely interlinked and multi-regulated crosstalk of insulin receptor signals, mitochondrial OXPHOS, and the antioxidant defense system in the hypothalamus and liver.

Exercício físico aeróbico de intensidade moderada reduz a velocidade de crescimento e modula o metabolismo energético tumoral em modelo experimental de câncer de mama triplo-negativo / Moderate-intensity aerobic physical exercise reduces tumor growth velocity and modulates tumor energy metabolism in the experimental model of triple-negative breast cancer

O câncer de mama ocupa o primeiro lugar em mortalidade dentre todos os tipos de câncer. O subtipo triplo-negativo (triple-negative breast cancer - TNBC) representa 15-20% de todos os tipos de câncer de mama com alta prevalência em mulheres pré-menopausa e destaca-se pelo seu grande tamanho tumoral e agressividade no estabelecimento de metástases, com impacto direto na redução da sobrevida dos pacientes. Apesar das evidências sobre os efeitos anti-tumorigênicos do exercício físico, tanto na prevenção como durante a carcinogênese, é comum que pacientes alterem sua rotina após o diagnóstico de câncer, frequentemente reduzindo as atividades físicas durante e após o tratamento. Em adição, os mecanismos pelos quais o exercício físico exerce papel anti-tumoral são pouco compreendidos. O objetivo deste estudo foi avaliar os efeitos do exercício físico aeróbico moderado em modelo experimental de câncer de mama de tipo triplo-negativo, com ênfase na modulação do metabolismo energético tumoral. Foram utilizados camundongos fêmeas BALB/c em desenho experimental de 12 semanas, cuja inoculação de 1x104 células 4T1 foi realizada após 8 semanas de treinamento. Após protocolo de exercício aeróbico moderado em esteira, foram realizadas análises do metabolismo mitocondrial tumoral, composição lipídica e expressão de genes relacionados à bioenergética e proliferação celular. Os resultados mostraram que o exercício aeróbico moderado reduziu 54,5% do volume e 42% da massa tumoral de animais que foram treinados antes e após a inoculação tumoral. Animais treinados apresentaram fosforilação oxidativa mais próxima ao seu limite máximo respiratório e menor respiração mitocondrial no tecido tumoral quando comparados ao grupo sedentário. O treinamento ocasionou redução no conteúdo de ácido fosfatídico e fosfatidilcolina. Enquanto a análise de expressão relativa de mRNA demonstrou aumento na expressão de genes relacionados à via metabólica glicolítica, como Hif1a, Glut-1, HKII, Ldha e Pdk, além dos supressores tumorais p53 e Lats2. Nossos resultados sugerem que a redução na velocidade de crescimento tumoral proporcionada pelo exercício físico aeróbico de carga moderada seja devida, pelo menos em parte, à modulação do metabolismo energético tumoral. Em conjunto, os dados do nosso estudo abrem novas perspectivas para a identificação de vias metabólicas sensíveis ao exercício físico, permitindo o melhor o entendimento de seus efeitos antitumorigênicos

Breast cancer ranks first in mortality among all types of cancer. The triple-negative breast cancer (TNBC) accounts for 15-20% of all types of breast cancer with a high prevalence in premenopausal women and is notable for its large tumor size and aggressiveness in the establishment of metastasis, with a direct impact on the reduction of patients' survival. Altough evidence highlight the anti-tumorigenic effects of physical exercise both on the prevention as well as during carcinogenesis, patients commonly change their routine after cancer diagnostic, usually reducing physical activity during and after treatment. Moreover, the mechanisms underlying the anti-tumor role of physical exercise remain poorly understood. The objective of this study was to evaluate the effects of moderate aerobic physical exercise in an experimental model of triple-negative breast cancer, with emphasis on the modulation of tumor energy metabolism. Female BALB / c mice were used in a 12-week experimental design, whose inoculation of 1x104 4T1 cells was performed after 8 weeks of training. After the protocol of moderate aerobic exercise was carried out on the treadmill, analyzes of mitochondrial tumor metabolism, lipid content and qPCR of genes related to bioenergetics and tumorigenic process were performed. The results showed that moderate aerobic exercise reduced 54.5% of the volume and 42% the tumor mass of animals trained before and after tumor inoculation. Trained animals showed oxidative phosphorylation closest to the maximum respiratory limit and lower mitochondrial respiration in tumor tissue when compared to the sedentary group. The training resulted in a reduction in the content of phosphatidic acid and phosphatidylcholine. In the trained group, relative mRNA quantification analysis showed increased expression of genes related to the glycolytic metabolic pathway, such as Hif1a, Glut-1, HKII, Ldha, and Pdk, as well as of the tumor suppressors p53 and Lats2. Our results suggest that the reduction in tumor growth velocity provided by moderate-intensity aerobic physical exercise is due, at least in part, to the modulation of tumor energy metabolism. Together, data from our study open new perspectives for the identification of metabolic pathways sensitive to exercise, allowing better understanding of its anti-tumorigenic effects

Mitochondrial proteomic profile of complex IV deficiency fibroblasts: rearrangement of oxidative phosphorylation complex/supercomplex and other metabolic pathways / Perfil proteómico mitocondrial de los fibroblastos con deficiencia del complejo IV: reordenamiento del complejo/supercomplejo de la fosforilación oxidativa y otras vías metabólicas

Abstract: Background: Mitochondriopathies are multisystem diseases affecting the oxidative phosphorylation (OXPHOS) system. Skin fibroblasts are a good model for the study of these diseases. Fibroblasts with a complex IV mitochondriopathy were used to determine the molecular mechanism and the main affected functions in this disease. Methods: Skin fibroblast were grown to assure disease phenotype. Mitochondria were isolated from these cells and their proteome extracted for protein identification. Identified proteins were validated with the MitoMiner database. Results: Disease phenotype was corroborated on skin fibroblasts, which presented a complex IV defect. The mitochondrial proteome of these cells showed that the most affected proteins belonged to the OXPHOS system, mainly to the complexes that form supercomplexes or respirosomes (I, III, IV, and V). Defects in complex IV seemed to be due to assembly issues, which might prevent supercomplexes formation and efficient substrate channeling. It was also found that this mitochondriopathy affects other processes that are related to DNA genetic information flow (replication, transcription, and translation) as well as beta oxidation and tricarboxylic acid cycle. Conclusions: These data, as a whole, could be used for the better stratification of these diseases, as well as to optimize management and treatment options.

Resumen: Introducción: Las mitocondriopatías son enfermedades multisistémicas que afectan el funcionamiento de la fosforilación oxidativa (OXPHOS). Un buen modelo de estudio para estas enfermedades es el cultivo primario de fibroblastos. En este trabajo se utilizaron fibroblastos con mitocondriopatía del complejo IV para determinar cuáles son las principales funciones afectadas en esta enfermedad. Métodos: Se realizaron cultivos primarios de fibroblastos para corroborar el fenotipo de la enfermedad. Las mitocondrias se aislaron de estas células y se extrajo su proteoma para su identificación. Las proteínas identificadas se validaron con la base de datos de MitoMiner. Resultados: Los fibroblastos conservaron el fenotipo de la enfermedad que incluye un defecto del complejo IV. El proteoma mitocondrial de estas células mostró que las proteínas más afectadas pertenecen al sistema de OXPHOS, principalmente los complejos que forman supercomplejos o respirosomas (I, III, IV y V). El defecto en el complejo IV al parecer se debió a problemas de ensamblaje que pueden evitar la formación de los supercomplejos y la eficiente canalización de sustratos. También se observó que esta mitocondriopatía afecta otros procesos relacionados con el flujo de información genética del DNA (replicación, transcripción y traducción), así como con la beta oxidación y el ciclo de los ácidos tricarboxílicos (TCA). Conclusiones: En conjunto, estos datos podrían utilizarse para una mejor clasificación de estas enfermedades, así como para la optimización de las opciones de manejo y tratamiento.

Mitochondria and tumors: A new perspective.

BACKGROUND: Mitochondrial DNA (Mt DNA) defects have been identified in a variety of Tumors, but the exact role of these defects in the pathogenicity and tumor progression is poorly understood. This study aims at identifying the status of mitochondrial OXPHOS genes in neoplastic transformation and attempts to establish a cause and effect relationship between mitochondrial OXPHOS defects and tumor progression. MATERIALS AND METHODS: Mutational, expression and functional analysis of l2 of the 13 mitochondrial OXPHOS genes has been carried out using PCR, Real-Time PCR and protein modeling in 180 sporadic samples of a heterogeneous group of benign and malignant tumors like that of benign, malignant, matched blood and adjacent normal tissue of breast and benign hemangioma. RESULTS: Mutations were identified in the ND4L, ND6 and COX-II regions of the mitochondrial OXPHOS genes. All the mutations were limited only to the malignant breast tissues. On relative quantification, a compromised expression of OXPHOS genes was identified in all the malignant tissues irrespective of their mutational states. Protein modeling revealed loss of function mutations of ND6 and COX-II proteins. CONCLUSION: This is the first study worldwide wherein a comparative study using different benign and malignant tumors has been carried out to assess the role of Mt DNA defects. Our data reveals mitochondrial dysfunction only in malignant cells and not in their benign counterparts, indicating that the dysfunction may arise after the pro-proliferative pathway has set in. We hypothesize that compromised OXPHOS may be a responsive mechanism of the cell to counter cancers, rather than a mechanism of initiating tumorigenesis.