MicroRNAs (miRNAs) play an essential role in the regulation of a number of physiologi-cal functions. miR-133a and other muscular miRs (myomiRs) play a key role in muscle cell growth and in some type of cancers. Here, we show that miR133a is upregulated in individuals that under-take physical exercise. We used a skeletal muscle differentiation model to dissect miR-133a’s role and to identify new targets, identifying Tropomyosin-4 (TPM4). This protein is expressed during muscle differentiation, but importantly it is an essential component of microfilament cytoskeleton and stress fibres formation. The microfilament scaffold remodelling is an essential step in cell transformation and tumour progression. Using the muscle system, we obtained valuable information about the microfilament proteins, and the knowledge on these molecular players can be transferred to the cytoskeleton rearrangement observed in cancer cells. Further investigations showed a role of TPM4 in cancer physiology, specifically, we found that miR-133a downregulation leads to TPM4 upregulation in colon carcinoma (CRC), and this correlates with a lower patient survival. At molecular level, we demonstrated in myocyte differentiation that TPM4 is positively regulated by the TA isoform of the p63 transcription factor. In muscles, miR-133a generates a myogenic stimulus, reduc-ing the differentiation by downregulating TPM4. In this system, miR-133a counteracts the differen-tiative TAp63 activity. Interestingly, in CRC cell lines and in patient biopsies, miR-133a is able to regulate TPM4 activity, while TAp63 is not active. The downregulation of the miR leads to TPM4 overexpression, this modifies the architecture of the cell cytoskeleton contributing to increase the invasiveness of the tumour and associating with a poor prognosis. These results add data to the interesting question about the link between physical activity, muscle physiology and protection against colorectal cancer. The two phenomena have in common the cytoskeleton remodelling, due to the TPM4 activity, that is involved in stress fibres formation.

Caporali, S., Calabrese, C., Minieri, M., Pieri, M., Tarantino, U., Marini, M., et al. (2021). The mir-133a, tpm4 and tap63γ role in myocyte differentiation microfilament remodelling and colon cancer progression. INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES, 22(18), 9818 [10.3390/ijms22189818].

The mir-133a, tpm4 and tap63γ role in myocyte differentiation microfilament remodelling and colon cancer progression

Minieri M.;Pieri M.;Tarantino U.;Marini M.;D'ottavio S.;Mauriello A.;Cortese C.;Bernardini S.;Terrinoni A.
2021-09-11

Abstract

MicroRNAs (miRNAs) play an essential role in the regulation of a number of physiologi-cal functions. miR-133a and other muscular miRs (myomiRs) play a key role in muscle cell growth and in some type of cancers. Here, we show that miR133a is upregulated in individuals that under-take physical exercise. We used a skeletal muscle differentiation model to dissect miR-133a’s role and to identify new targets, identifying Tropomyosin-4 (TPM4). This protein is expressed during muscle differentiation, but importantly it is an essential component of microfilament cytoskeleton and stress fibres formation. The microfilament scaffold remodelling is an essential step in cell transformation and tumour progression. Using the muscle system, we obtained valuable information about the microfilament proteins, and the knowledge on these molecular players can be transferred to the cytoskeleton rearrangement observed in cancer cells. Further investigations showed a role of TPM4 in cancer physiology, specifically, we found that miR-133a downregulation leads to TPM4 upregulation in colon carcinoma (CRC), and this correlates with a lower patient survival. At molecular level, we demonstrated in myocyte differentiation that TPM4 is positively regulated by the TA isoform of the p63 transcription factor. In muscles, miR-133a generates a myogenic stimulus, reduc-ing the differentiation by downregulating TPM4. In this system, miR-133a counteracts the differen-tiative TAp63 activity. Interestingly, in CRC cell lines and in patient biopsies, miR-133a is able to regulate TPM4 activity, while TAp63 is not active. The downregulation of the miR leads to TPM4 overexpression, this modifies the architecture of the cell cytoskeleton contributing to increase the invasiveness of the tumour and associating with a poor prognosis. These results add data to the interesting question about the link between physical activity, muscle physiology and protection against colorectal cancer. The two phenomena have in common the cytoskeleton remodelling, due to the TPM4 activity, that is involved in stress fibres formation.
11-set-2021
Pubblicato
Rilevanza internazionale
Articolo
Esperti anonimi
Settore BIO/12 - BIOCHIMICA CLINICA E BIOLOGIA MOLECOLARE CLINICA
English
Circulating miRs
Colon carcinoma (CRC), TAp63
MiR-133a
MiRNAs
Physical activity
TPM4
Tropomyosins
Actin Cytoskeleton
Carcinogenesis
Cell Differentiation
Cell Line, Tumor
Cell Proliferation
Colonic Neoplasms
Cytoskeleton
Gene Expression Regulation, Neoplastic
Humans
MicroRNAs
Muscle Cells
Muscle Development
Muscle, Skeletal
Stress Fibers
Transcription Factors
Tropomyosin
Tumor Suppressor Proteins
Caporali, S., Calabrese, C., Minieri, M., Pieri, M., Tarantino, U., Marini, M., et al. (2021). The mir-133a, tpm4 and tap63γ role in myocyte differentiation microfilament remodelling and colon cancer progression. INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES, 22(18), 9818 [10.3390/ijms22189818].
Caporali, S; Calabrese, C; Minieri, M; Pieri, M; Tarantino, U; Marini, M; D'Ottavio, S; Angeletti, S; Mauriello, A; Cortese, C; Bernardini, S; Terrino...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2108/284657
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