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Function of Rho GTPase Activating Protein 11A in Tumors.

Byline: Hui-Nian. Zhou, Yan-Xian. Ren, Long. Li, Ke-Shen. Wang, Zuo-Yi. Jiao

To the Editor: Rho GTPase Activating Protein 11A ( ArhGAP11A ) is a member of the Rho GTPase-activating proteins ( Rho GAPs ) gene family and is located on the long arm of 15 chromosome region 1 band 3 subband 2 (15q13.3). The full-length cDNA of ArhGAP11A is 24,806 bp with a single open-reading frame. ArhGAP11A is encoded by 13 exons and the encoded protein has three domains: a RhoGAP domain near the N terminus (amino acids 46-246), and two uncharacterized domains respectively located in the center (387-516) and C terminus (590-997) of the protein.[1] Kagawa et al. [2] compared the expression of ArhGAP11A in 74 colorectal cancer tissue specimens and five noncancerous mucosal tissue specimens with cDNA microarray-based comparative analyses. The results showed that ArhGAP11A expression was significantly higher in colorectal cancer tissue than that in noncancerous tissue, indicating that the upregulation of ArhGAP11A expression is beneficial to colorectal cancer cells in vivo migration and invasion activity. Ciriello et al .[3] analyzed the RNA sequential data of 1201 patients with invasive breast lobular cancer, but only a few of the 64 Rho GAPs were found to be highly expressed in the basal-like breast cancer. Further study [4] showed that the expression of ArhGAP11A in basal-like breast cancer was generally higher than other types of breast cancer, and in vitro experiments showed that ArhGAP11A overexpression could stimulate normal breast cancer cell proliferation. ArhGAP11A expression was also found to be upregulated in glioblastoma, hepatocellular, and pancreatic cancers. Based on these findings, the abnormal expression of ArhGAP11A might be closely related to the occurrence and development of tumors.

The cell cycle progression depends on the E2F transcription factor family. The role of E2F1 is regulated by the Rb protein, as dephosphorylated Rb protein is able to bind to E2F1 and inhibit the binding of E2F1 to specific DNA sequences. After phosphorylation of Rb protein by cyclin-dependent kinases (CDKs), E2F1 is released from the inhibitory complex of Rb/E2F1; it then binds to its dimerization partner (DP), either DP1 or DP2. This forms a heterodimeric E2F1/DP1 structure that combines with the target gene's promoter sequence (TTTSSCGCS, S = G or C) to initiate transcriptional activity of the gene. Kagawa et al. [2] found that the binding of Rb protein to E2F1 hindered the transcriptional activity of the ArhGAP11A promoter, indicating that the Rb/E2F1 signaling pathway might be related to the transcriptional activity of ArhGAP11A. These authors suggested that the phosphorylation inactivation of tumor-inhibiting factor Rb protein might lead to abnormal activity of E2Fs causing in an increased ArhGAP11A expression. However, Lawson et al. [4] found that when ArhGAP11A expression was inhibited, the expression of p27 and the CDKs inhibitor CDKN2A/p27 was increased. This led to the breakdown of the complex formed between CDKs and cyclin D1 and E and decreased phosphorylation inactivation of tumor suppressor protein Rb1. Ultimately, this reduced the release of E2F inhibitor, inhibited cells from the G1 phase to S phase transition, and eventually caused cell cycle arrest. Both of these studies showed that Rb/E2F1 pathway can regulate ArhGAP11A expression; however, the role of E2Fs remains controversial. Therefore, the CDKN2A/p27/Rb/E2F1 pathway might be a molecular signaling pathway for ArhGAP11A expression.

Several studies have shown that ArhGAP11A can regulate the biological activity of Rho A, which is involved in tumor cell invasion and metastasis.[1],[2],[4],[5] The GTP structure of Rho A can stimulate the formation of focal adhesions and stress fibers by activating Rho-associated protein kinase (ROCK) or mammalian diaphanous protein. In vitro experiments showed that ROCK inhibitor could inhibit Rho-mediated signal pathway and cause cell morphology change similar to that of ArhGAP11A overexpression. A recent study [6] also showed that Skp1-Cul1-F-box FBXL19 mediates Rho A ubiquitination and degradation. Therefore, we believe that inhibiting ArhGAP11A expression might reduce Rho A ubiquitination and degradation but increase its activity. This would continue to activate ROCK as well as the phosphorylation of ROCK downstream substrates, which is involved in the regulation of the cytoskeleton. Phosphorylation of ROCK downstream substrates also promotes the formation of tension fibers and focal adhesions, thus inhibiting the invasion and metastasis of tumors. Although the biological function of the Rho A pathway is obviously controversial and needs further study, the ArhGAP11A/Rho A/ROCK pathway might be an important signaling pathway for regulating the biological functions of ArhGAP11A in tumor cell proliferation, invasion, and metastasis.

ArhGAP11A is overexpressed in a variety of tumors; it plays an important role in the proliferation, invasion, metastasis, and cell cycle regulation of tumor cells. ArhGAP11A expression is significantly increased in highly aggressive tumors (e.g., glioblastoma and pancreatic cancer), and inhibition of ArhGAP11A could significantly reduce the possibility of tumor invasion and metastasis. In summary, ArhGAP11A might be a new marker for tumor diagnosis or as a new target for tumor therapy.

Financial support and sponsorship

This work was supported by grants from the Health Industry Scientific Research Program of Gansu province (No. GSWSKY2016-03), and the Key Research and Development Program of Gansu province (No. 17YF1FA127).

Conflicts of interest

There are no conflicts of interest.


1. Xu J, Zhou X, Wang J, Li Z, Kong X, Qian J, et al. RhoGAPs attenuate cell proliferation by direct interaction with p53 tetramerization domain. Cell Rep 2013;3:1526-38. doi: 10.1016/j.celrep.2013.04.017.

2. Kagawa Y, Matsumoto S, Kamioka Y, Mimori K, Naito Y, Ishii T, et al. Cell cycle-dependent Rho GTPase activity dynamically regulates cancer cell motility and invasion in vivo . PLoS One 2013;8:e83629. doi: 10.1371/journal.pone.0083629.

3. Ciriello G, Gatza ML, Beck AH, Wilkerson MD, Rhie SK, Pastore A, et al. Comprehensive molecular portraits of invasive lobular breast cancer. Cell 2015;163:506-19. doi: 10.1016/j.cell.2015.09.033.

4. Lawson CD, Fan C, Mitin N, Baker NM, George SD, Graham DM, et al. Rho GTPase transcriptome analysis reveals oncogenic roles for Rho GTPase-activating proteins in basal-like breast cancers. Cancer Res 2016;76:3826-37. doi: 10.1158/0008-5472.CAN-15-2923.

5. Zanin E, Desai A, Poser I, Toyoda Y, Andree C, Moebius C, et al. A conserved RhoGAP limits M phase contractility and coordinates with microtubule asters to confine RhoA during cytokinesis. Dev Cell 2013;26:496-510. doi: 10.1016/j.devcel.2013.08.005.

6. Wei J, Mialki RK, Dong S, Khoo A, Mallampalli RK, Zhao Y, et al. A new mechanism of RhoA ubiquitination and degradation: Roles of SCF(FBXL19) E3 ligase and Erk2. Biochim Biophys Acta 2013;1833:2757-64. doi: 10.1016/j.bbamcr.2013.07.005.
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Title Annotation:Correspondence
Author:Zhou, Hui-Nian; Ren, Yan-Xian; Li, Long; Wang, Ke-Shen; Jiao, Zuo-Yi
Publication:Chinese Medical Journal
Article Type:Letter to the editor
Date:Nov 1, 2018
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