Cargando…

foxm1 Modulates Cell Non-Autonomous Response in Zebrafish Skeletal Muscle Homeostasis

foxm1 is a master regulator of the cell cycle, contributing to cell proliferation. Recent data have shown that this transcription factor also modulates gene networks associated with other cellular mechanisms, suggesting non-proliferative functions that remain largely unexplored. In this study, we us...

Descripción completa

Detalles Bibliográficos
Autores principales:	Ferreira, Fábio J., Carvalho, Leonor, Logarinho, Elsa, Bessa, José
Formato:	Online Artículo Texto
Lenguaje:	English
Publicado:	MDPI 2021
Materias:	Communication
Acceso en línea:	https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8158134/ https://www.ncbi.nlm.nih.gov/pubmed/34070077 http://dx.doi.org/10.3390/cells10051241

Ejemplares similares

FOXM1 repression increases mitotic death upon antimitotic chemotherapy through BMF upregulation
por: Vaz, Sara, et al.
Publicado: (2021)

FoxM1 repression during human aging leads to mitotic decline and aneuploidy-driven full senescence
por: Macedo, Joana Catarina, et al.
Publicado: (2018)

Role of the phosphocreatine system on energetic homeostasis in skeletal and cardiac muscles
por: Guimarães-Ferreira, Lucas
Publicado: (2014)

FOXM1 and Cancer: Faulty Cellular Signaling Derails Homeostasis
por: Kalathil, Dhanya, et al.
Publicado: (2021)

NO-sGC Pathway Modulates Ca(2+) Release and Muscle Contraction in Zebrafish Skeletal Muscle
por: Xiyuan, Zhou, et al.
Publicado: (2017)

FOXM1: Functional Roles of FOXM1 in Non-Malignant Diseases
por: Zhang, Zhenwang, et al.
Publicado: (2023)

TAK1 modulates satellite stem cell homeostasis and skeletal muscle repair
por: Ogura, Yuji, et al.
Publicado: (2015)

THE LOCATION OF SODIUM IN THE TRANSVERSE TUBULES OF SKELETAL MUSCLE
por: Zadunaisky, Jose A.
Publicado: (1966)

Heart and Skeletal Muscles: Linked by Autonomic Nervous System
por: Araujo, Claudio Gil, et al.
Publicado: (2019)

Autophagy in Skeletal Muscle Homeostasis and in Muscular Dystrophies
por: Grumati, Paolo, et al.
Publicado: (2012)

Rho GTPases in Skeletal Muscle Development and Homeostasis
por: Rodríguez-Fdez, Sonia, et al.
Publicado: (2021)

Hepatic sialic acid synthesis modulates glucose homeostasis in both liver and skeletal muscle
por: Peng, Jun, et al.
Publicado: (2023)

Foxm1 regulates cardiomyocyte proliferation in adult zebrafish after cardiac injury
por: Zuppo, Daniel A., et al.
Publicado: (2023)

FOXM1 predicts disease progression in non-muscle invasive bladder cancer
por: Rinaldetti, Sebastien, et al.
Publicado: (2018)

Zebrafish Fins as a Model System for Skeletal Human Studies
por: Marí-Beffa, Manuel, et al.
Publicado: (2007)

Human skeletal muscle tissue chip autonomous payload reveals changes in fiber type and metabolic gene expression due to spaceflight
por: Parafati, Maddalena, et al.
Publicado: (2023)

Structure and Function of Skeletal Muscle in Zebrafish Early Larvae
por: Dou, Ying, et al.
Publicado: (2008)

Skeletal muscle regeneration in Xenopus tadpoles and zebrafish larvae
por: Rodrigues, Alexandre Miguel Cavaco, et al.
Publicado: (2012)

Xirp Proteins Mark Injured Skeletal Muscle in Zebrafish
por: Otten, Cécile, et al.
Publicado: (2012)

Determination of the source of SHG verniers in zebrafish skeletal muscle
por: Dempsey, William P., et al.
Publicado: (2015)

Cell‐autonomous defects contribute to insulin resistance in skeletal muscle
por: Fujita, Yoshihito, et al.
Publicado: (2021)

Skeletal Muscle Homeostasis in Duchenne Muscular Dystrophy: Modulating Autophagy as a Promising Therapeutic Strategy
por: De Palma, Clara, et al.
Publicado: (2014)

The role of skeletal muscle Akt in the regulation of muscle mass and glucose homeostasis
por: Jaiswal, N., et al.
Publicado: (2019)

Beta-agonist drugs modulate the proliferation and differentiation of skeletal muscle cells in vitro
por: Flavie Ouali, Boimpoundi Eunice, et al.
Publicado: (2021)

Hsp60 in Skeletal Muscle Fiber Biogenesis and Homeostasis: From Physical Exercise to Skeletal Muscle Pathology
por: Marino Gammazza, Antonella, et al.
Publicado: (2018)

Sarcolemmal ATP-sensitive potassium channels modulate skeletal muscle function under low-intensity workloads
por: Zhu, Zhiyong, et al.
Publicado: (2014)

Smyd3 Is Required for the Development of Cardiac and Skeletal Muscle in Zebrafish
por: Fujii, Tomoaki, et al.
Publicado: (2011)

In vivo myosin step-size from zebrafish skeletal muscle
por: Burghardt, Thomas P., et al.
Publicado: (2016)

Mutual Regulation of FOXM1, NPM and ARF Proteins
por: Pandit, Bulbul, et al.
Publicado: (2015)

Attractors under autonomous and non-autonomous perturbations
por: Bortolan, Matheus C, et al.
Publicado: (2020)

MECHANISM OF EMPTYING OF SKELETAL MUSCLE CELL SEGMENTS
por: Stanley, D. W., et al.
Publicado: (1968)

Regulation of Skeletal Muscle Function by Amino Acids
por: Kamei, Yasutomi, et al.
Publicado: (2020)

Tissue engineering strategies for human hair follicle regeneration: How far from a hairy goal?
por: Castro, Ana Rita, et al.
Publicado: (2019)

MeCP2 Affects Skeletal Muscle Growth and Morphology through Non Cell-Autonomous Mechanisms
por: Conti, Valentina, et al.
Publicado: (2015)

Skeletal muscle–specific eukaryotic translation initiation factor 2α phosphorylation controls amino acid metabolism and fibroblast growth factor 21–mediated non–cell-autonomous energy metabolism
por: Miyake, Masato, et al.
Publicado: (2016)

Aberrant Mitochondrial Homeostasis in the Skeletal Muscle of Sedentary Older Adults
por: Safdar, Adeel, et al.
Publicado: (2010)

MEHP interferes with mitochondrial functions and homeostasis in skeletal muscle cells
por: Chen, Yi-Huan, et al.
Publicado: (2020)

Editorial: Calcium Homeostasis in Skeletal Muscle Function, Plasticity, and Disease
por: Mosqueira, Matias, et al.
Publicado: (2021)

Distinct roles of UVRAG and EGFR signaling in skeletal muscle homeostasis
por: Kim, Min Jeong, et al.
Publicado: (2021)

Maintenance of NAD+ Homeostasis in Skeletal Muscle during Aging and Exercise
por: Ji, Li Li, et al.
Publicado: (2022)

Cannot write session to /tmp/vufind_sessions/sess_bi9n3vankmd7sv26mb57rb2v10