RESUMEN
El oxígeno y dióxido de carbono son vitales en la respiración, sus variaciones fuera del rango fisiológico son una amenaza para la supervivencia de las células. La hipoxia es una condición común en la mayoría de los tumores malignos, la cual promueve angiogénesis y vascularización disfuncional, mayor proliferación celular y la adquisición de un fenotipo de transición epitelial a mesenquimatoso, que contribuye con la metástasis; asimismo, altera el metabolismo de las células cancerosas y genera resistencia a la terapia, ya que induce a la inactividad celular. Por tanto, la hipoxia es un factor negativo, asociado a resultados adversos en la mayoría de los tratamientos de los distintos tipos de cáncer. El factor inducible por hipoxia (HIF) es el factor de transcripción relacionado con la hipoxia en cáncer, que produce la activación de más de una centena de genes reguladores de la actividad celular, que generan funciones cruciales para el desarrollo del cáncer. El objetivo principal de la presente revisión es puntualizar la importancia de la hipoxia en la génesis del cáncer, conocer las principales moléculas que interactúan en la expresión del HIF, explicar los mecanismos moleculares de las vías involucradas en la inducción del HIF, las consecuencias celulares por su alteración y las potenciales terapias dirigidas contra este factor. Se consultaron PubMed, Scopus y SciELO, del año 1990 hasta el año 2022, y se buscaron las referencias bibliográficas en relación con las palabras clave asociadas al factor inducible por hipoxia y cáncer. En conclusión, la sobreexpresión de HIF-1α en biopsias tumorales se asocia con una mayor mortalidad de pacientes en cánceres humanos. Los posibles genes diana regulados por HIF-1α que pueden desempeñar un papel en la progresión tumoral están empezando a descubrirse. A pesar de que se han estudiado cientos de compuestos en relación con el HIF en cáncer, en la actualidad existen pocos inhibidores del HIF aprobados en el mercado mundial; asimismo, muchos estudios clínicos, en sus distintas fases en desarrollo, no muestran resultados alentadores. Probablemente, en el futuro, cuando se tenga una mejor comprensión de la estructura, funcionamiento molecular y biológico de este factor, se desarrollarán fármacos más específicos para la inhibición del HIF.
Oxygen and carbon dioxide are essential for breathing; variations in these gases outside of the normal range are a threat to cell survival. Hypoxia is a common condition that occurs in most malignant tumors, increases angiogenesis and defective vascularization, promotes cell proliferation and acquires an epithelial-mesenchymal transition phenotype, which causes metastasis. It also affects cancer cell metabolism and makes patients resistant to treatment by causing cell quiescence. As a result, hypoxia is a detrimental component that is linked to unfavorable outcomes in most cancer treatments. Through the activation of more than a hundred genes that control cell activity, which produce key functions for cancer development, the transcription factor known as hypoxia-inducible factor (HIF) is linked to hypoxia in cancer. This review's main goals are to highlight the role of hypoxia in the development of cancer, identify the key molecules that interact to promote HIF expression, explain the molecular mechanisms of the pathways that lead to HIF induction, describe the cellular effects of HIF alteration, and discuss potential HIF-targeted therapies. Articles from 1990 to 2022 were reviewed in PubMed, Scopus and SciELO databases. Keywords related to cancer and HIF were searched in bibliographical references. In conclusion, HIF-1α overexpression in tumor biopsies is associated with increased patient mortality in human cancers. Potential HIF-1α-regulated target genes that may play a role in tumor progression are starting to be identified. Although hundreds of chemicals have been studied in relation to HIF in cancer, there are currently few approved HIF inhibitors available on the global market; moreover, many clinical trials, in their various stages of development, do not show encouraging results. It is likely that in the future, when there is a better understanding of the structure, molecular and biological functioning of this factor, more specific drugs for HIF inhibition will be developed.
RESUMEN
Hypoxia-inducible factor 1alpha (HIF-1alpha) is rapidly degraded by the ubiquitin-proteasome pathway under normoxic conditions. Ubiquitination of HIF-1alpha is mediated by interaction with von Hippel-Lindau tumor suppressor protein (pVHL). In our previous report, we found that hypoxia-induced active signal transducer and activator of transcription3 (STAT3) accelerated the accumulation of HIF-1alpha protein and prolonged its half-life in solid tumor cells. However, its specific mechanisms are not fully understood. Thus, we examined the role of STAT3 in the mechanism of pVHL-mediated HIF-1alpha stability. We found that STAT3 interacts with C-terminal domain of HIF-1alpha and stabilizes HIF-1alpha by inhibition of pVHL binding to HIF-1alpha. The binding between HIF-1alpha and pVHL, negative regulator of HIF-1alpha stability, was interfered dose-dependently by overexpressed constitutive active STAT3. Moreover, we found that the enhanced HIF-1alpha protein levels by active STAT3 are due to decrease of poly-ubiquitination of HIF-1alpha protein via inhibition of interaction between pVHL and HIF-1alpha. Taken together, our results suggest that STAT3 decreases the pVHL-mediated ubiquitination of HIF-1alpha through competition with pVHL for binding to HIF-1alpha, and then stabilizes HIF-1alpha protein levels.