TY - JOUR
T1 - Revisiting the Warburg effect in cancer cells with proteomics. The emergence of new approaches to diagnosis, prognosis and therapy
AU - Scatena, Roberto
AU - Bottoni, Patrizia
AU - Pontoglio, Alessandro
AU - Giardina, Bruno
PY - 2010
Y1 - 2010
N2 - Most cancer cells exhibit elevated levels of glycolysis and this metabolic
pathway seems to be related to a greater glucose uptake. This phenomenon, known
as the Warburg effect, is considered one of the most fundamental metabolic
alterations during malignant transformation. Originally, Warburg hypothesised
that the aerobic glycolysis of cancer cells could be just an aspect of a more
complex metabolic adaptation. However, this intriguing discovery was partially
misinterpreted and disregarded over time. In recent years, the peculiarities of
cancer cell metabolism have been re-evaluated in light of new metabolic data that
seem to confirm and to widen the original concept of the Warburg effect. In fact,
biochemical, molecular, and, above all, proteomic studies on the multifaceted
roles of glycolytic enzymes in cancer cells in general, and in cancer stem cells
in particular, seem to suggest more complex functional adaptations. These
adaptations result in significantly altered protein expression patterns, and they
have fundamental implications for diagnosis, prognosis and therapy. Revisiting
the Warburg effect in cancer cells with a proteomic approach could deepen our
knowledge of cancer cell metabolism and of cancer cell biology in general.
Moreover, by identifying useful diagnostic, prognostic and therapeutic targets,
it could significantly impact clinical practice.
AB - Most cancer cells exhibit elevated levels of glycolysis and this metabolic
pathway seems to be related to a greater glucose uptake. This phenomenon, known
as the Warburg effect, is considered one of the most fundamental metabolic
alterations during malignant transformation. Originally, Warburg hypothesised
that the aerobic glycolysis of cancer cells could be just an aspect of a more
complex metabolic adaptation. However, this intriguing discovery was partially
misinterpreted and disregarded over time. In recent years, the peculiarities of
cancer cell metabolism have been re-evaluated in light of new metabolic data that
seem to confirm and to widen the original concept of the Warburg effect. In fact,
biochemical, molecular, and, above all, proteomic studies on the multifaceted
roles of glycolytic enzymes in cancer cells in general, and in cancer stem cells
in particular, seem to suggest more complex functional adaptations. These
adaptations result in significantly altered protein expression patterns, and they
have fundamental implications for diagnosis, prognosis and therapy. Revisiting
the Warburg effect in cancer cells with a proteomic approach could deepen our
knowledge of cancer cell metabolism and of cancer cell biology in general.
Moreover, by identifying useful diagnostic, prognostic and therapeutic targets,
it could significantly impact clinical practice.
KW - cancer cell metabolism
KW - cancer stem cells
KW - mitochondria
KW - cancer cell metabolism
KW - cancer stem cells
KW - mitochondria
UR - http://hdl.handle.net/10807/9014
M3 - Article
SN - 1862-8346
SP - 143
EP - 158
JO - PROTEOMICS. CLINICAL APPLICATIONS
JF - PROTEOMICS. CLINICAL APPLICATIONS
ER -