Title: Role of PI3K/Akt/Pten in tumorigenesis: a link between inflammation and reprogramming of the host metabolism |
Authors: García López, Lucía |
Tutor: Domínguez Castellano, María Villegas Nieto, Santiago Nahuel |
Editor: Universidad Miguel Hernández |
Department: Instituto de Neurociencias |
Issue Date: 2021-05-21 |
URI: https://hdl.handle.net/11000/28207 |
Abstract:
Although cancer begins locally, symptoms associated with disease progression can be
manifested systemically and be extremely debilitating for the patient. Identifying the
genes that drive and mediate both local and systemic effects of tumorigenesis is
important not only for developing treatments aimed at targeting cancer, but also for
maintaining and improving patient quality of life. Here we use a multidisciplinary
approach to uncover new mechanisms underlying Notch-PI3K/Akt-driven
tumorigenesis in a well-established cancer paradigm in Drosophila melanogaster with
highly predictive value (Palomero et al., 2007; Villegas et al., 2018). First, we designed
an unbiased in vivo chemical screen to identify drugs that can selectively dampen this
oncogenic cooperation without side effects. We identified a novel nitric oxide-
dependent inflammatory pathway that is associated with Notch/Pten-dependent
oncogenesis and perhaps amenable to pharmacological intervention.
On the other hand, phospho-proteomic analysis of these tumors revealed that
aberrant PI3K/Akt signaling fuels Notch tumorigenesis in part by triggering
mitochondrial dysfunction and generating oxidative stress. Our results also indicate that
stress-activated Jnk signal might be restricting tumor progression by inducing apoptosis,
and therefore acting as a tumor suppressor in this context.
Surprisingly, we found that Notch-PI3K/Akt tumors not only consume high
amounts of glucose, but also remotely alter whole-body metabolism. High throughput
large-scale and tissue-specific metabolomics revealed an unexpected interplay between
the tumor and the host tryptophan-kynurenine metabolism, especially in the fat body,
which ultimately leads to a systemic inflammation. Moreover, we detected changes
related to tryptophan metabolism in the hemolymph, gut microbiota and brain of tumor-
bearing hosts, further confirming for the first time that tumors can induce a multi-organ
metabolic reprogramming. Consequently, diet supplementation with tryptophan was
sufficient to prevent tumor formation through different multi-layered mechanisms.
These findings could have important implications, since dietary interventions may hold
the promise for the development of better treatments against cancer.
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Keywords/Subjects: Oncología Biología molecular |
Knowledge area: CDU: Ciencias aplicadas: Medicina: Patología. Medicina clínica. Oncología: Neurología. Neuropatología. Sistema nervioso |
Type of document: application/pdf |
Access rights: info:eu-repo/semantics/openAccess Attribution-NonCommercial-NoDerivatives 4.0 Internacional |
Appears in Collections: Tesis doctorales - Ciencias de la Salud
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