The TUSC7, or LINC00902, is a long non-coding RNA (lncRNA) located on chromosome 3q13.31. Though first identified as a tumor suppressor in colorectal cancer, TUSC7 has subsequently been found to play a ubiquitous role in a wide range of cancers, such as non-small cell lung cancer (NSCLC), gastric cancer (GC), osteosarcoma, pancreatic carcinoma, and others. As a tumor suppressor, TUSC7 is most directly associated with the regulation of cellular proliferation, differentiation, and apoptosis, which are all central processes in cancer biology. It accomplishes this by interacting with various molecular targets, including oncogenic microRNAs (oncomiRs), chromatin remodeling complexes, and major cell cycle regulators. The role of TUSC7 in cancer has made it a focal point for understanding the intricate web of gene regulation, as well as its potential application as a diagnostic and therapeutic target. Tumor suppressor candidate 7's tumor-suppressive function is mainly attributed to its role as a molecular sponge for oncomiRs, small non-coding RNAs that typically promote cancer development by suppressing the expression of tumor-suppressor genes. Through the sequestration of oncomiRs, TUSC7 inhibits their binding to target genes, and the expression of tumor-suppressor genes is thus restored. It is an important step in TUSC7's regulatory function in major cellular functions, including cell cycle control, apoptosis, migration, and invasion — processes whose deregulation plays an important role in cancer development and progression (
17-
22).
In CRC, TUSC7's tumor-suppressing function was reported earlier. The lncRNA functions by directly binding the oncogenic microRNA miR-211-3p, effectively sequestering it so that it is no longer able to target CDK6, a cyclin-dependent kinase that promotes cell cycle progression from G1 to S phase. Through the inhibition of miR-211-3p's capacity to suppress CDK6, TUSC7 triggers cell cycle arrest and represses excessive cell proliferation, a hallmark of cancer development. Consequently, TUSC7 downregulation in CRC has been linked with aggressive tumor behavior, increased proliferation, and lower patient survival rates. The molecular interaction of miR-211-3p with TUSC7 is a reflection of how lncRNAs play a role in regulating cancer progression through the modulation of oncomiRs and cell cycle regulators (
23).
In GC, TUSC7 serves a fundamental function in preserving a balance between pro-apoptotic and anti-apoptotic signaling. Research indicates that TUSC7 is linked to miR-23b, an oncomiR that targets and inhibits a number of pro-apoptotic genes. Through its binding to miR-23b, TUSC7 inhibits the inhibitory action of miR-23b on these pro-apoptotic genes, thus inducing apoptosis and inhibiting the growth and viability of cancer cells. In the case of TUSC7 loss or downregulation of expression, the inhibition of these pro-apoptotic genes leads to increased cell survival, resistance to apoptosis, and hence more aggressive cancer phenotypes. Loss of TUSC7 expression has been associated with poor prognosis in GC patients, highlighting the important function of this lncRNA in the maintenance of cellular homeostasis and the prevention of malignant transformation (
24).
The regulatory role of TUSC7 extends beyond its miRNA interaction. In osteosarcoma, a highly malignant bone cancer common in children and young adults, TUSC7 has also been found to bind chromatin-modifying complexes, suggesting that its tumor suppressor function can also be through epigenetic regulation. Tumor suppressor candidate 7 thereby helps to regulate gene expression of the osteosarcoma cell proliferation, invasion, and metastasis genes. Downregulation of TUSC7 expression in osteosarcoma cells results in increased cellular motility and invasiveness, which is partly responsible for the poor prognosis and high metastatic rate of this particular malignancy (
25,
26).
Further, in NSCLC, TUSC7 is demonstrated to be an important regulator of cell cycle progression and metastatic activity. In this carcinoma, TUSC7 functions as a potent suppressor of tumor growth by acting against several oncomiRs like miR-10b, which has been identified to regulate genes involved in cell migration and invasion. Non-small cell lung cancer overexpression of miR-10b has been linked with the promotion of metastatic potential, and TUSC7 suppresses this function by preventing miR-10b from downregulating its target genes. This dialogue reflects the complex role of TUSC7 in controlling the formation of tumors and their secondary spreading, an important prognostic determinant of cancer (
27-
29).
In pancreatic cancer, which is considered to be among the deadliest cancer types with high mortality rates, the levels of TUSC7 expression tend to be decreased, and the lack thereof has been linked with poor survival rates. The exact pathways by which TUSC7 regulates pancreatic cancer formation are under active research. However, as in other cancers, TUSC7's tumor suppressor role in pancreatic carcinoma is believed to be exerted through its binding of oncogenic miRNAs and its control of cell survival and apoptosis genes (
30).
Despite the mounting body of evidence that supports the tumor-suppressive role of TUSC7 in many cancers, the exact molecular mechanisms through which it acts remain to be elucidated. However, it is clear that TUSC7 mediates its actions through a range of mechanisms, including the direct modulation of oncomiRs and binding with chromatin-modifying complexes, hence influencing gene expression at both transcriptional and post-transcriptional levels. Furthermore, reduction or downregulation of TUSC7 expression has been consistently associated with poorer clinical outcomes in a wide range of malignancies, thereby highlighting its function as a major tumor suppressor. These observations imply that restoration or mimicry of TUSC7 function would be a useful treatment in those cancers where it is lost, such as colorectal cancer, GC, and osteosarcoma (
31,
32).
However, the role of TUSC7 in AML, while promising, is yet to be determined. The genetic complexity and heterogeneity of AML may influence the manner in which TUSC7 functions in this hematologic cancer. Current evidence indicates that TUSC7 may play a comparable role in AML, regulating genes implicated in cell differentiation, apoptosis, and leukemogenesis. The study of TUSC7's role in AML is of the utmost importance as it can provide new insights into the molecular biology of the disease and open up therapeutic options.