Inmunopatología de la brucelosis osteoarticular / Immunopathology of osteoarticular brucelosis

La brucelosis es una de las enfermedades zoonóticas más importantes a nivel mundial capaz de producir enfermedad crónica en los seres humanos. La localización osteoarticular es la presentación más común de la enfermedad activa en el hombre. Sin embargo, algunos de los mecanismos moleculares implicados en la enfermedad osteoarticular han comenzado a dilucidarse recientemente. Brucella abortus induce daño óseo a través de diversos mecanismos en los cuales están implicados TNF-α y RANKL. En estos procesos participan células inflamatorias que incluyen monocitos/macrófagos, neutrófilos, linfocitos T del tipo Th17 y linfocitos B. Además, B. abortus puede afectar directamente las células osteoarticulares. La bacteria inhibe la deposición de la matriz ósea por los osteoblastos y modifica el fenotipo de estas células para producir metaloproteinasas de matriz (MMPs) y la secreción de citoquinas que contribuyen a la degradación del hueso. Por otro lado, la infección por B. abortus induce un aumento en la osteoclastogénesis, lo que aumenta la resorción de la matriz ósea orgánica y mineral y contribuye al daño óseo. Dado que la patología inducida por Brucella afecta el tejido articular, se estudió el efecto de la infección sobre los sinoviocitos. Estos estudios revelaron que, además de inducir la activación de estas células para secretar quemoquinas, citoquinas proinflamatorias y MMPs, la infección inhibe la muerte por apoptosis de los sinoviocitos. Brucella es una bacteria intracelular que se replica en el retículo endoplásmico de los macrófagos. El análisis de los sinoviocitos infectados con B. abortus indicó que las bacterias también se multiplican en el retículo endoplasmático, lo que sugiere que la bacteria podría usar este tipo celular para la multiplicación intracelular durante la localización osteoarticular de la enfermedad. Los hallazgos presentados en esta revisión intentan responder a preguntas sobre los mediadores inflamatorios implicados en el daño osteoarticular causado por Brucella. (AU)

Brucellosis is one of the most important zoonotic diseases that can produce chronic disease in humans worldwide. Osteoarticular involvement is the most common presentation of human active disease. The molecular mechanisms implicated in bone damage have started to be elucidated. B. abortus induces bone damage through diverse mechanisms in which TNF-α and RANKL are implicated. These processes are driven by inflammatory cells, including monocytes/macrophages, neutrophils, Th17 lymphocytes and B cells. Also, Brucella abortus (B. abortus) can directly affect osteoarticular cells. The bacterium inhibits bone matrix deposition by osteoblast and modifies the phenotype of these cells to produce matrix methalloproteinases (MMPs) and cytokine secretion that contribute to bone matrix degradation. B. abortus also affects osteoclast increasing mineral and organic bone matrix resorption and contributing to bone damage. Since the pathology induced by Brucella species involves joint tissue, experiments conducted in sinoviocytes revealed that besides inducing the activation of these cells to secrete chemokines, proinflammatory cytokines and MMPS, the infection also inhibits sinoviocyte apoptosis. Brucella is an intracellular bacterium that replicate in the endoplasmic reticulum of macrophages. The analysis of B. abortus infected sinoviocytes indicated that bacteria also replicate in their reticulum suggesting that the bacterium could use this cell type for intracellular replication during the osteoarticular localization of the disease. The findings presented in this review try to answer key questions about the inflammatory mediators involved in osteoarticular damage caused by Brucella. (AU)

Nineteen Types of WNT Genes Mediate The Differentiation of C3H10T1/2 Cell Lines / 대한정형외과연구학회지

PURPOSE: In humans, nineteen types of WNT genes (WNTs) have been hightlighted up to date. The canonical Wnt cascade has recently emerged as a critical regulator of stem cells. To obtain new insights how nineteen WNTs affect mesenchymal stem cells differentiation, we analyzed the transcriptional activity, osteogenic and adipogenic activity of WNTs in mesenchymal stem cells. MATERIALS AND METHODS: Recombinant adenoviruses expressing nineteen WNTs were constructed to infect pluripotent mesenchymal progenitor C3H10T1/2 cells. Transcriptional activity was determined by using the luciferase reporter assay. Osteogenic activity was determined by measuring the induction of alkaline phosphatase upon Wnt stimulation. Adipogenic activity was measured by histochemical Oil red-O staining. RESULTS: WNT1, 2, 3, 3A and 10B significantly induced transcriptional activity in C3H10T1/2 cells. WNT1, 2, 3, 3A and 10B significantly induced alkaline phosphatase activity, but inhibited adipogenic activity in C3H10T1/2 cells. The results of qualitative and quantitative assay of alkaline phosphatase activity were consistent with those of luciferase assay for transcriptional activity and Oil red-O staining for adipogenic activity. CONCLUSION: We could expect that WNT1, 2, 3, 3A and 10B may play a crucial role in inducing osteoblast differentiation of mesenchymal stem cells.