Background Diabetes is now afflicting an expanding population, and it has become a major source of concern for human health. Diabetes affects several organs and causes chronic damage and dysfunction. It is one of the three major diseases that are harmful to human health. Plasmacytoma variant translocation 1 is a member of long non-coding RNA. PVT1 expression profile abnormalities have been reported in diabetes mellitus and its consequences in recent years, suggesting that it may contribute to the disease's progression. Methods Relevant literature from the authoritative database “PubMed” are retrieved and summarized in detail. Results Mounting evidence reveals that PVT1 has multiple functions. Through sponge miRNA, it can participate in a wide variety of signal pathways and regulate the expression of a target gene. More importantly, PVT1 is crucially implicated in the regulation of apoptosis, inflammation, and so on in different types of diabetes-related complications. Conclusion PVT1 regulates the occurrence and progression of diabetes-related diseases. Collectively, PVT1 has the potential to be a useful diagnostic and therapeutic target for diabetes and its consequences.
Tobacco mosaic virus (TMV) is a rod-shaped hollow plant viral nanoparticle (300 nm × 18 nm) and exhibits abundant amino acid residues on its surface of capsid proteins for facile...
Background: Long chain non-coding RNAs (lncRNA) are a kind of transcript that is around 200 nucleotides long and can engage in life activities via epigenetic, transcriptional, and post-transcriptional regulation. One of the key members of lncRNAs, long stress-induced noncoding transcripts 5 (LSINCT5), is localized at Chr 5p and has been reported to be abnormally expressed in a range of cancers. We present a comprehensive review of LSINCT5's aberrant expression and regulatory mechanisms in malignant tumors. Method: The included studies were retrieved and summarized through the PubMed database using the keywords “LSINCT5” and “Cancer” in detail. Results: LSINCT5 behaves as an oncogene and abundantly expresses in malignant tumorigenesis and progression. By sponging microRNAs (miRNA), interacting with proteins, participating in cellular transduction, and being regulated by transcription factors, LSINCT5 can stimulate malignant behavior in a variety of tumor cells, including proliferation, migration, invasion, and epithelial-mesenchymal transition (EMT). Furthermore, dysregulated LSINCT5 is usually associated with a poor prognosis. Conclusion: LSINCT5 has the potential to become a tumor diagnostic and prognostic marker, generating new access to clinical applications.
Background: NR2F1-AS1 is a long non-coding RNA (lnc RNA) that is involved in different biological processes. It plays an integral role in the pathophysiology of human diseases, especially tumorigenesis and progression. Therefore, it may be a promising target for numerous tumor biotherapeutics. The current review study aimed to show the pathophysiological activities and processes of RNA NR2F1-AS1 in cancer cells. Methods: The contents of the present review were based on information obtained from PubMed. In the data search, “NR2F1-AS1” was chosen as the first keyword, whereas “cancer” was chosen as the second keyword. This review selected and summarized studies published between 2019-2021, concerning the biological functions and mechanisms of NR2F1-AS1 in the development of tumorigenesis. Results: It was found that NR2F1-AS1 regulates a variety of biological activities such as proliferation, invasion, migration, and apoptosis. It acts as an oncogene because it is abnormally expressed and promotes the progression of cancer in a variety of malignancies, including esophageal squamous cell carcinoma, non-small cell lung cancer, breast cancer, neuroblastoma, endometrial cancer, thyroid cancer, and gastric cancer. However, it was evident that NR2F1-AS1 inhibits the progression of cancer in cervical squamous cell carcinoma. Conclusion: NR2F1-AS1 is a potential new biomarker and therapeutic target for the treatment of different cancers.
Background: Eph receptors tyrosine kinase (RTK) were identified in 1987 from hepatocellular carcinoma cell lines and were the largest known subfamily of RTK. Eph receptors can be divided into two categories, EphA and EphB, based on their structure and receptor-ligand specificity. EphA can be divided into 10 species (EphA 1-10), and EphB into 6 species (EphB1-6). Similarly, the ligands of Eph receptors are Ephrins. Ephrins also can be divided into Ephrin A and Ephrin B, of which there are five species(Ephrin-A1-5) and three species(Ephrin-B1-3). Among the Eph receptors, EphA1 has been the least studied so far. As far as we know, Eph receptors are involved with multiple pathologies, including cancer progression, tumor angiogenesis, intestinal environmental stability, the lymph node system, neurological disease, and inhibition of nerve regeneration after injury. There is a link between EphA1, integrin and ECM- related signal pathways. Ephrin-A1 is a ligand of the EphA1 receptor. EphA1 and ephrin-A1 functions are related to tumor angiogenesis. EphA1 and ephrin-A1 also play roles in gynecological diseases. Ephrin-A1 and EphA1 receptor regulate follicular formation, ovulation, embryo transport, implantation and placental formation, which are of great significance for the occurrence of gynecological tumor diseases: EphA1 has been identified as an oncoprotein in various tumors, and is associated with the prognosis of a variety of tumors in recent years. EphA1 is considered a driver gene in tumor genomics. There are significant differences in EphA1 expression levels in different types of normal tissues and tumors, and even in different stages of tumor development, suggesting its functional diversity. Changes at the gene level in cell biology are often used as biological indicators of cancer, known as biomarkers, which can be used to provide diagnostic or prognostic information and are valuable for improving the detection, monitoring and treatment of tumors. However, few prognostic markers can selectively predict clinically significant tumors with poor prognosis. These malignancies are more likely to progress and lead to death, requiring more aggressive treatment. Currently available treatments for advanced cancer are often ineffective, and treatment options are mainly palliative. Therefore, early identification and treatment of those at risk of developing malignant tumors are crucial. Although pieces of evidence have shown the role of EphA1 in tumorigenesis and development, its specific mechanism is still unknown to a great extent. Objective: This review reveals the changes and roles of EphA1 in many tumors and cancers. The change of EphA1 expression can be used as a biological marker of cancer, which is valuable for improving tumor detection, monitoring and treatment, and can be applied to imaging. Studies have shown that structural modification of EphA1 could make it an effective new drug. EphA1 is unique in that it can be considered a prognostic marker in many tumors and is of important meaning for clinical diagnosis and operative treatment. At the same time, the study of the specific mechanism of EphA1 in tumors can provide a new way for targeted therapy. Methods: Relevant studies were retrieved and collected through the PubMed system. After determining EphA1 as the research object, by analyzing research articles on EphA1 in the PubMed system in recent 10 years, we found that EphA1 was closely connected with the occurrence and development of tumors, and further determined the references according to the influencing factors for review and analysis. Results: EphA1 has been identified as a cancer protein in various tumors, such as hepatocellular carcinoma, nasopharyngeal carcinoma, ovarian cancer, gastric cancer, colorectal cancer, clear cell renal cell carcinoma, esophageal squamous cell carcinoma, breast cancer, prostate cancer and uveal melanoma. EphA1 is abnormally expressed in these tumor cells, which mainly plays a role in cancer progression, tumor angiogenesis, intestinal environmental stability, the lymph node system, nervous system diseases and gynecological diseases. In a narrow sense, EphA1 is especially effective in breast cancer in terms of gynecological diseases. However, the specific mechanism of EphA1 leading to the change of cancer cells in some tumors is not clear, which needs further research and exploration. Conclusion: RTK EphA1 can be used as a biomarker for tumor diagnosis (especially a prognostic marker), an indispensable therapeutic target for new anti-tumor therapies, and a novel anti-tumor drug.
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