The p38 MAPK Components and Modulators as Biomarkers and Molecular Targets in Cancer
Abstract
:1. Introduction
2. The p38 MAPK Pathway
2.1. p38 MAPK Activation and Regulation
2.1.1. p38 MAPK Regulation by Phosphatases
2.1.2. p38 MAPK Pathway Regulation by microRNAs
2.2. Substrates and Subcellular Localization of p38 MAPK
3. Role of the p38 MAPK Pathway in Cancer
3.1. Proliferation, Survival, and Differentiation
3.2. Metastasis in Relationship with Migration and Inflammation
4. A New Approach: p38β, p38γ, and p38δ Isoforms as Cancer Biomarkers
5. p38 as a Pharmacological Target in Cancer
5.1. Impact of p38 in Radiotherapy
5.2. Involvement of p38 in Chemotherapy
5.3. Drugs with Pharmacological Potential Targeting the p38 MAPK Pathway
6. Conclusions and Future Perspectives
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Treatment | Clinical/Preclinical Trial Title | Study Features | Clinicaltrials.gov Identifier/Reference |
---|---|---|---|
Ralimetinib (LY2228820) + Carboplatin + Gemcitabine | A study LY2228820 for recurrent ovarian cancer | Clinical trial Phase Ib/II Targeting p38α and p38β isoforms by combining the action of carboplatin radiotherapy with carboplatin and gemcitabine chemotherapy | NCT01663857 |
Ralimetinib + Tamoxifen | A multicenter trial assessing the efficacy and safety of Tamoxifen Plus LY2228820 in advanced or metastatic breast cancer progressing on aromatase inhibitors (OLYMPE) | Clinical trial Phase II Targeting p38α and p38β isoforms by combining the action of tamoxifen therapy, a selective estrogen receptor modulator | NCT02322853 |
Ralimetinib + Midazolam + Tamoxifen | A study of LY2228820 in participants with advanced cancer | Clinical trial Phase I Targeting p38α and p38β isoforms by combining the action of tamoxifen therapy, a selective estrogen receptor modulator with midazolam, to promote the pharmacological action of compounds | NCT01393990 |
Ralimetinib + Temolozomide (TMZ) + Radiotherapy | Study of LY2228820 with radiotherapy Plus concomitant TMZ in the treatment of newly diagnosed glioblastoma (GLYRad) | Clinical trial Phase I/II Targeting p38α and p38β isoforms by combining the action of TMZ, aimed at inhibiting cell proliferation | NCT02364206 |
Prexasertib 1 (LY2606368) + Ralimetinib | A study of Prexasertib (LY2606368) in combination with Ralimetinib in participants with advanced or metastatic cancer | Clinical trial Phase I Targeting p38α and p38β isoforms by combining the action of a checkpoint kinase inhibitor | NCT02860780 |
Talmapimod (SCIO-469) | Open-label study for patients with myelodysplastic syndromes | Clinical trial Phase II Targeting selectively p38α isoform, although it also shows selectivity on p38β and other MAPKs | NCT00113893 |
rCisplatin + PH-797804 | Inhibition of p38 MAPK sensitizes tumor cells to cisplatin-induced apoptosis mediated by reactive oxygen species and JNK | Murine model with induced mammary tumors. p38 inhibition enhances cisplatin cytotoxicity | [140] |
CDD-111 and CDD-450 | Inhibition of the stromal p38MAPK/MK2 pathway limits breast cancer metastases and chemotherapy-induced bone loss | Murine model implanted with cancer cells. p38 inhibition enhances cisplatin cytotoxicity | [141] |
Sorafenib and BIRB796, L-skepinone or PH-797804 | In vivo RNAi screening identifies a mechanism of sorafenib resistance in liver cancer | Murine model with NRASG12V and p19Arf-knockout liver tumors. p38 inhibition increases therapeutic efficacy of sorafenib | [142] |
PH-797804 | Dual function of p38α MAPK in colon cancer: suppression of colitis-associated tumor initiation but requirement for cancer cell survival | Murine model with AOM/DSS inflammation-driven colon tumors. p38 inhibition reduces colon tumor load | [143] |
PF3644022 + PF477736 | A synergistic interaction between Chk1- and MK2 inhibitors in KRAS-mutant cancer | Murine model with KRASG12D and Tp53-knockout lung tumors, high-grade sarcomas or BRAF-driven intestinal carcinomas. Combined inhibition of MK2 and CHK1 induces cytostatic or cytotoxic effects in different tumor types | [144] |
BIRB796 | Multi-phenotype CRISPR-Cas9 screen identifies p38 kinase as a target for adoptive immunotherapies | Mice with subcutaneously implanted melanoma cell line B16-mhgp100 or injected with the acute lymphoblastic leukemia cell line E2a-PBX. p38 inhibition in T cells ex vivo increases their immunosuppression properties in vivo | [145] |
LY2228820 | Blockade of p38 kinase impedes the mobilization of protumorigenic myeloid populations to impact breast cancer metastasis | Mice with mammary tumors formed by implantation of the mouse mammary carcinoma cell line 4T1. p38 inhibition reduces tumor growth and recruitment of protumoral myeloid cells | [146] |
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García-Hernández, L.; García-Ortega, M.B.; Ruiz-Alcalá, G.; Carrillo, E.; Marchal, J.A.; García, M.Á. The p38 MAPK Components and Modulators as Biomarkers and Molecular Targets in Cancer. Int. J. Mol. Sci. 2022, 23, 370. https://doi.org/10.3390/ijms23010370
García-Hernández L, García-Ortega MB, Ruiz-Alcalá G, Carrillo E, Marchal JA, García MÁ. The p38 MAPK Components and Modulators as Biomarkers and Molecular Targets in Cancer. International Journal of Molecular Sciences. 2022; 23(1):370. https://doi.org/10.3390/ijms23010370
Chicago/Turabian StyleGarcía-Hernández, Laura, María Belén García-Ortega, Gloria Ruiz-Alcalá, Esmeralda Carrillo, Juan Antonio Marchal, and María Ángel García. 2022. "The p38 MAPK Components and Modulators as Biomarkers and Molecular Targets in Cancer" International Journal of Molecular Sciences 23, no. 1: 370. https://doi.org/10.3390/ijms23010370
APA StyleGarcía-Hernández, L., García-Ortega, M. B., Ruiz-Alcalá, G., Carrillo, E., Marchal, J. A., & García, M. Á. (2022). The p38 MAPK Components and Modulators as Biomarkers and Molecular Targets in Cancer. International Journal of Molecular Sciences, 23(1), 370. https://doi.org/10.3390/ijms23010370