Demethylation of Secreted Frizzled-Related Protein2( SFRP2) Promoter Upregulates Wnt/β-Catenin Activity in Endometriosis

Wnt/β-catenin signalling contributes to the metastasis and invasion in the etiology and pathogenesis of endometriosis (EMS), but why the WNT pathway is dysregulated in EMS remains unclear. This study aimed to explore the effects of demethylation of SFRP2 promoter on the Wnt/β-catenin activity in EMS. Aberrantly methylated-differentially expressed genes were identified from GEO database microarray data. 5 ectopic endometrium and 5 normal endometrium were get, subsequently, ectopic endometrium epithelial cells (EEECs) and normal endometrium epithelial cells (NEECs) were isolated in vitro. MSP, BSP, luciferase reporter assay, Lentivirus infection of high expression of SFRP2 gene vector, low expression of DNMT1 gene vector, and 5-Aza stimulation, RT-PCR and western blot were performed in the tissues or cells. It was found that compared with the normal endometrium and NEECs, the RNA and protein expression levels of SFRP2 were significantly increased while the SFRP2 promoter was demethylated in ectopic endometrium and EEECs. The 5-Aza treatment significantly upregulated SFRP2 mRNA and protein levels in EEECs. Furthermore, after the knockdown of DNMT1 expression, the demethylation of the SFRP2 promoter and upregulation of SFRP2 mRNA and protein in EEECs were observed. Meanwhile, the expression of lentivirus carrying SFRP2 cDNA up-regulates the activity of Wnt signaling and the protein expression of β-catenin in EEECs. In summary, the increased SFRP2 expression-induced Wnt/β-catenin signaling due to the demethylation of the SFRP2 promoter plays an important role in the pathogenesis of EMS, suggesting that SFRP2 might be a therapeutic target for EMS treatment.

The Collective Effect of MIP-3α and FL Promotes Dendritic Cell Function Within the Immune Microenvironment of Murine Liver Cancer

Hepatocellular carcinoma is a highly malignant and lethal tumor. In addition to surgery, immunotherapy is currently a more effective treatment for hepatocellular carcinoma. The tumor immune microenvironment (TIME) largely determines the efficacy of cancer immunotherapy. Based on the universal targeting of TIME modulators in clinical treatment, TIME modulators are promising targets for tumor immunotherapy. We investigated the effect of a double gene expression vector (recombinant galactose-terminal glycol-poly-L-lysine coupled MIP-3α-FL) on dendritic cells (DCs) regulation within the TIME of mice with liver cancer. H22 cells were transfected with a recombinant MIP-3α-FL plasmid to induce DCs differentiation and chemotaxis. The effects of transfection were investigated by flow cytometry following the modified Boyden’s method. Cytokine-induced killer (CIK) cells co-culture revealed changes in the antigen presentation ability of DCs. Further, tumor-bearing mice were injected with the recombinant double gene vector via the tail vein. We compared the survival time, tumor volume, weight of the mice, as well as the number and phenotype of tumor-infiltrating DCs (TIDCs) between groups. The supernatant of transfected H22 cells promoted the phenotypic maturation of DCs, enhancing their chemotaxis. Further, treated DCs promoted the cytokine secretion and killing ability of CIK cells. The survival time of mice injected with the double gene vector was significantly prolonged, while their tumor weight and volume were relatively reduced. Flow cytometry revealed that the number of TIDCs (as well as CD80 and CD86 expression) in the MouseMIP-3α-FL group, were significantly higher than in the control group. The combination of MIP-3α and FL can significantly promote DCs aggregation, maturation, and enhance their antigen presentation ability. The coupling of the double gene vector with glycosylated polylysine can improve the precise targeting of the liver and inhibit tumor growth in vivo, providing a novel approach for immune therapy in liver cancer.

Jumping Ahead with Sleeping Beauty: Mechanistic Insights into Cut-and-Paste Transposition

Sleeping Beauty (SB) is a transposon system that has been widely used as a genetic engineering tool. Central to the development of any transposon as a research tool is the ability to integrate a foreign piece of DNA into the cellular genome. Driven by the need for efficient transposon-based gene vector systems, extensive studies have largely elucidated the molecular actors and actions taking place during SB transposition. Close transposon relatives and other recombination enzymes, including retroviral integrases, have served as useful models to infer functional information relevant to SB. Recently obtained structural data on the SB transposase enable a direct insight into the workings of this enzyme. These efforts cumulatively allowed the development of novel variants of SB that offer advanced possibilities for genetic engineering due to their hyperactivity, integration deficiency, or targeting capacity. However, many aspects of the process of transposition remain poorly understood and require further investigation. We anticipate that continued investigations into the structure–function relationships of SB transposition will enable the development of new generations of transposition-based vector systems, thereby facilitating the use of SB in preclinical studies and clinical trials.

Applications and Functions of γ-Poly-Glutamic Acid and its Derivatives in Medicine

Background: γ-Poly-glutamic acid (γ-PGA) is a naturally occurring homo-polyamide produced by various strains of Bacillus. It is made from repeating units of L-glutamic acid, D-glutamic acid, or both connected through amide linkages between α-amino and γ-carboxylic acid groups. As a biopolymer substance, the attractive properties of γ-PGA are that it is water-soluble, biodegradable, biocompatible, non-toxic, non-immunogenic, and edible. Therefore, it can be used as a green and environmentally friendly biological material. Methods: The review concentrates on the reports revealing the functions and potential use of γ-PGA and its derivatives in medicine. Results & Discussion: γ-PGA is described to possess several properties which may be exploited in medicine. The biopolymer reportedly has been successfully applied not only as metal chelator, drug carrier/deliverer, and gene vector, but also used safely as vaccine adjuvant, tissue engineering material, and contrast agent. Conclusion: γ-PGA could be potentially considered as a potential biomedical material in the field of medicine.