mTORC1-dependent AMD1 regulation sustains polyamine metabolism in prostate cancer

Zabala-Letona, Amaia; Arruabarrena-Aristorena, Amaia; Martín-Martín, Natalia; Fernández-Ruiz, Sonia; Sutherland, James D.; Clasquin, Michelle; Tomás-Cortázar, Julen; Jimenez, José; Torres, Inés Cristina; Quang, Phong; Ximénez-Embún, Pilar; Bago, Ružica; Ugalde-Olano, Aitziber; Loizaga-Iriarte, Ana; Lacasa-Viscasillas, Isabel; Unda, Miguel; Torrano, Verónica; Cabrera, Diana; Liempd, Sebastiaan van; Cendón, Ylenia; Castro, Elena; Murray, Stuart; Revandkar, Ajinkya; Alimonti, Andrea; Zhang, Yinan; Barnett, Amelia; Lein, Gina; Pirman, David; Cortazar, Ana R.; Arreal, Leire; Prudkin, Ludmila; Astobiza, Ianire; Valcárcel-Jiménez, Lorea; Zúñiga-García, Patricia; Fernández-Domínguez, Itziar; Piva, Marco; Caro‐Maldonado, Alfredo; Sánchez-Mosquera, Pilar; Castillo-Martín, Mireia; Serra, Violeta; Beraza, Naiara; Gentilella, Antonio; Thomas, George I.; Azkargorta, Mikel; Elortza, Félix; Farràs, Rosa; Olmos, David; Efeyan, Alejo; Anguíta, Juan; Muñoz, Javier; Falcón‐Pérez, Juan Manuel; Barrio, Rosa; Macarulla, Teresa; Mato, José M.; Martínez‐Chantar, María Luz; Cordon‐Cardo, Carlos; Aransay, Ana M.; Marks, Kevin M.; Baselga, José; Tabernero, Josep; Nuciforo, Paolo; Manning, Brendan D.; Marjon, Katya; Carracedo, Arkaitz

doi:10.1038/nature22964

Cited by 152 publications

(157 citation statements)

References 47 publications

(56 reference statements)

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“…SOD1 however has been only recently been proposed as a novel target for cancer therapy [24] and its role in cancer is also being revealed [25]. More recently being elucidated is the role of AMD1 in cancer which has been found to be upregulated in human prostate cancer [26]. NOS2 is another one which has been recently being seen as a emerging target for cancer treatment [27][28].…”

Section: Resultsmentioning

confidence: 99%

Protein-Protein Interaction Network Analysis and Identification of Key Players in nor-NOHA and NOHA Mediated Pathways for Treatment of Cancer through Arginase Inhibition: Insights from Systems Biology

Ahammad

2018

Preprint

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L-arginine is involved in a number of biological processes in our bodies. Metabolism of Larginine by the enzyme arginase has been found to be associated with cancer cell proliferation. Arginase inhibition has been proposed as a potential therapeutic means to inhibit this process. Nhydroxy-nor-L-Arg (nor-NOHA) and N (omega)-hydroxy-L-arginine (NOHA) has shown promise in inhibiting cancer progression through arginase inhibition. In this study, nor-NOHA and NOHA-associated genes and proteins were analyzed with several Bioinformatics and Systems Biology tools to identify the associated pathways and the key players involved so that a more comprehensive view of the molecular mechanisms including the regulatory mechanisms can be achieved and more potential targets for treatment of cancer can be discovered. Based on the analyses carried out, 3 significant modules have been identified from the PPI network. Five pathways/processes have been found to be significantly associated with nor-NOHA and NOHA associated genes. Out of the 1996 proteins in the PPI network, 4 have been identified as hub proteins-SOD, SOD1, AMD1, and NOS2. These 4 proteins have been implicated in cancer by other studies. Thus, this study provided further validation into the claim of these 4 proteins being potential targets for cancer treatment.

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Section: Resultsmentioning

confidence: 99%

Protein-Protein Interaction Network Analysis and Identification of Key Players in nor-NOHA and NOHA Mediated Pathways for Treatment of Cancer through Arginase Inhibition: Insights from Systems Biology

Ahammad

2018

Preprint

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“…However, the larger picture of mTORC1-mediated metabolic regulation and how it drives cellular oncogenesis is still an active and attractive area of research. In a recent issue of Nature , Zabala-Letona et al (2017) demonstrate that in addition to the previously reported roles in driving anabolic processes, mTORC1 regulates polyamine flux to promote cell proliferation and growth in prostate cancer.…”

mentioning

confidence: 86%

“…Reporting recently in Nature , Zabala-Letona et al (2017) show that mTORC1 regulates an additional branch of metabolism in the cell—polyamine synthesis—that is important for prostate cancer tumorigenicity. …”

mentioning

confidence: 99%

“…Interestingly, Zabala-Letona et al (2017) show that polyamine metabolism is the main metabolic pathway altered in PTEN loss-driven prostate cancers in both animal models and human biopsies. The authors set out to explore how polyamine synthesis is altered in these cancers and determined it to be dependent on mTORC1 activation.…”

mentioning

confidence: 99%

“…These results add a new layer of metabolic regulation by mTORC1 to support cellular growth and proliferation, as well as reaffirm the role of mTORC1 as a major regulator of cellular homeostasis (Figure 1). Though Zabala-Letona et al (2017) elegantly show that the mTORC1 signaling network regulates AMD1 phosphorylation, precisely how it happens remains unclear. Therefore, determining which mTORC1-regulated kinase is the missing link between mTORC1 activity and AMD1 regulation remains an important open question before the complete understanding of this mTORC1 regulatory network is achieved.…”

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confidence: 99%

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Adding Polyamine Metabolism to the mTORC1 Toolkit in Cell Growth and Cancer

2017

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The role of lipoylation in mitochondrial adaptation to methionine restriction

Xue,

2024

BioEssays

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Dietary methionine restriction (MR) is associated with a spectrum of health‐promoting benefits. Being conducive to prevention of chronic diseases and extension of life span, MR can activate integrated responses at metabolic, transcriptional, and physiological levels. However, how the mitochondria of MR influence metabolic phenotypes remains elusive. Here, we provide a summary of cellular functions of methionine metabolism and an overview of the current understanding of effector mechanisms of MR, with a focus on the aspect of mitochondria‐mediated responses. We propose that mitochondria can sense and respond to MR through a modulatory role of lipoylation, a mitochondrial protein modification sensitized by MR.

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mTORC1-dependent AMD1 regulation sustains polyamine metabolism in prostate cancer

Cited by 152 publications

References 47 publications

Protein-Protein Interaction Network Analysis and Identification of Key Players in nor-NOHA and NOHA Mediated Pathways for Treatment of Cancer through Arginase Inhibition: Insights from Systems Biology

Protein-Protein Interaction Network Analysis and Identification of Key Players in nor-NOHA and NOHA Mediated Pathways for Treatment of Cancer through Arginase Inhibition: Insights from Systems Biology

Adding Polyamine Metabolism to the mTORC1 Toolkit in Cell Growth and Cancer

The role of lipoylation in mitochondrial adaptation to methionine restriction

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