BACKGROUND: Cardiac regenerative medicine is a rapidly evolving field, with promising future developments for effective personalized treatments. Several stem/progenitor cells are candidates for cardiac cell therapy, and emerging evidence suggests how multiple metabolic and biochemical pathways strictly regulate their fate and renewal. SCOPE OF REVIEW: In this review, we will explore a selection of areas of common interest for biology and biochemistry concerning stem/progenitor cells, and in particular cardiac progenitor cells. Numerous regulatory mechanisms have been identified that link stem cell signaling and functions to the modulation of metabolic pathways, and vice versa. Pharmacological treatments and culture requirements may be exploited to modulate stem cell pluripotency and self-renewal, possibly boosting their regenerative potential for cell therapy. MAJOR CONCLUSIONS: Mitochondria and their many related metabolites and messengers, such as oxygen, ROS, calcium and glucose, have a crucial role in regulating stem cell fate and the balance of their functions, together with many metabolic enzymes. Furthermore, protein biochemistry and proteomics can provide precious clues on the definition of different progenitor cell populations, their physiology and their autocrine/paracrine regulatory/signaling networks. GENERAL SIGNIFICANCE: Interdisciplinary approaches between biology and biochemistry can provide productive insights on stem/progenitor cells, allowing the development of novel strategies and protocols for effective cardiac cell therapy clinical translation. This article is part of a Special Issue entitled Biochemistry of Stem Cells.
BACKGROUND: Cardiac regenerative medicine is a rapidly evolving field, with promising future developments for effective personalized treatments. Several stem/progenitor cells are candidates for cardiac cell therapy, and emerging evidence suggests how multiple metabolic and biochemical pathways strictly regulate their fate and renewal. SCOPE OF REVIEW: In this review, we will explore a selection of areas of common interest for biology and biochemistry concerning stem/progenitor cells, and in particular cardiac progenitor cells. Numerous regulatory mechanisms have been identified that link stem cell signaling and functions to the modulation of metabolic pathways, and vice versa. Pharmacological treatments and culture requirements may be exploited to modulate stem cell pluripotency and self-renewal, possibly boosting their regenerative potential for cell therapy. MAJOR CONCLUSIONS: Mitochondria and their many related metabolites and messengers, such as oxygen, ROS, calcium and glucose, have a crucial role in regulating stem cell fate and the balance of their functions, together with many metabolic enzymes. Furthermore, protein biochemistry and proteomics can provide precious clues on the definition of different progenitor cell populations, their physiology and their autocrine/paracrine regulatory/signaling networks. GENERAL SIGNIFICANCE: Interdisciplinary approaches between biology and biochemistry can provide productive insights on stem/progenitor cells, allowing the development of novel strategies and protocols for effective cardiac cell therapy clinical translation. This article is part of a Special Issue entitled Biochemistry of Stem Cells.
Authors: Mariangela Peruzzi; Elena De Falco; Antonio Abbate; Giuseppe Biondi-Zoccai; Isotta Chimenti; Marzia Lotrionte; Umberto Benedetto; Ronak Delewi; Antonino G M Marullo; Giacomo Frati Journal: Biomed Res Int Date: 2015-06-15 Impact factor: 3.411
Authors: Isotta Chimenti; Francesca Pagano; Elena Cavarretta; Francesco Angelini; Mariangela Peruzzi; Antonio Barretta; Ernesto Greco; Elena De Falco; Antonino G M Marullo; Sebastiano Sciarretta; Giuseppe Biondi-Zoccai; Giacomo Frati Journal: Sci Rep Date: 2016-11-14 Impact factor: 4.379
Authors: Daniela Bastianelli; Camilla Siciliano; Rosa Puca; Andrea Coccia; Colin Murdoch; Antonella Bordin; Giorgio Mangino; Giulio Pompilio; Antonella Calogero; Elena De Falco Journal: Biomed Res Int Date: 2014-05-22 Impact factor: 3.411