[Effect of Hypoxia on CD47 Expression in Human Acute Myeloid Leukemia Cell Lines].

OBJECTIVE: To investigate the effect of hypoxia on hypoxia-inducible factor 1α (HIF-1α) and CD47 expression in human acute myeloid leukemia (AML) cell lines. METHODS: The CD47 expression in AML U937, HL-60, and K562 cells lines were detected by flow cytometry. U937, HL-60, and K562 cells were all divided into hypoxia-treated group and conventional oxygen group. The hypoxia-treated group was cultured with 1% O2, while the conventional oxygen group was cultured with 20% O2, then the cells were collected after 24 hours. Real time PCR was used to examine the mRNA changes of CD47 gene. Western blot assay was applied to detect the protein expression of HIF-1α and CD47. RESULTS: The expression of CD47 in U937, HL-60, and K562 cells was 98% (98%±0.03%), 99% (99%±0.05%), and 75% (75%±0.11%), respectively. The real time PCR showed that the mRNA expression of CD47 in U937 and HL-60 cells were up-regulated in the hypoxia-treated group (P<0.05), while in K562 cells was not (P>0.05). Western blot result showed that the protein levels of HIF-1α and CD47 of U937, HL-60, and K562 cells in the hypoxia-treated group were increased compared with the conventional oxygen group (P<0.05). CONCLUSION: The hypoxia can up-regulate the expression of CD47 in acute myeloid leukemia cells, which may be related to HIF-1α.

Evaluation of a five-gene signature associated with stromal infiltration for diffuse large B-cell lymphoma.

BACKGROUND: Diffuse large B-cell lymphoma (DLBCL) is a common non-Hodgkin lymphoma. The development of immunotherapy greatly improves the patient prognosis but there are some exceptions. Thus, screening for better biomarkers for prognostic evaluation could contribute to the treatment of DLBCL patients. AIM: To screen the novel mediators involved in the development of DLBCL. METHODS: The GSE60 dataset was applied to identify the differentially expressed genes (DEGs) in DLBCL, and the principal components analysis plot was used to determine the quality of the included samples. The protein-protein interactions were analyzed by the STRING tool. The key hub genes were entered into to the GEPIA database to determine their expressions in DLBCL. Furthermore, these hub gene alterations were analyzed in cBioportal. The UALCAN portal was employed to analyze the expression of the hub genes in different stages of DLBCL. The Estimation of Stromal and Immune cells in Malignant Tumor tissues using Expression data Score was conducted to evaluate the correlation between the gene expression and tumor purity. The gene-gene correlation analysis was conducted in the GEPIA. The stromal score analysis was conducted in TIMER to confirm the correlation between the gene expression and infiltrated stromal cells. The correlation between the indicated genes and infiltration level of cancer-associated fibroblasts (CAFs) was also completed in TIMER with two methods, MCP-Counter and Tumor immune dysfunction and exclusion. The correlation between fibronectin (FN1) protein level and secreted protein acidic and cysteine-rich (SPARC) messenger ribonucleic acid expression was confirmed in the cBioportal. RESULTS: The top 20 DEGs in DLBCL were identified, and the principal components analysis plot confirmed the quality of the significant DEGs. The pairwise correlation coefficient analysis among all samples showed that these DEGs have a certain co-expression pattern. The DEGs were subjected to STRING to identify the hub genes, alpha-2-macroglobulin (A2M), cathepsin B (CTSB), FN1, matrix metallopeptidase 9 (MMP9), and SPARC. The five hub genes were confirmed to be overexpressed in DLBCL. The cBioportal portal detected these five hub genes that had gene alteration, including messenger ribonucleic acid high amplification and missense mutation, and the gene alteration percentages of A2M, FN1, CTSB, MMP9, and SPARC were 5%, 8%, 5%, 2.7%, and 5%, respectively. Furthermore, the five hub genes had a potential positive correlation with tumor stage. The correlation analysis between the five genes and tumor purity confirmed that the five genes were overexpressed in DLBCL and had a positive correlation with the development of DLBCL. More interestingly, the five genes had a significant correlation with the stromal infiltration scores. The correlation analysis between the fives genes and CAFs also showed a significant value, among which the top two genes, FN1 and SPARC, had a remarkable co-expression pattern. CONCLUSION: The top DEGs were identified, and the five hub genes were overexpressed in DLBCL. Furthermore, the gene alterations were confirmed and the positive correlation with tumor purity revealed the overexpression of the five genes and close association with the development of DLBCL. More interestingly, the five genes were positively correlated with stromal infiltration, especially in CAFs. The top two genes, FN1 and SPARC, showed a co-expression pattern, which indicates their potential as novel therapeutic targets for DLBCL.

Chemoenzymatic synthesis and antileukemic activity of novel C9- and C14-functionalized parthenolide analogs.

Parthenolide is a naturally occurring terpene with promising anticancer properties, particularly in the context of acute myeloid leukemia (AML). Optimization of this natural product has been challenged by limited opportunities for the late-stage functionalization of this molecule without affecting the pharmacologically important α-methylene-γ-lactone moiety. Here, we report the further development and application of a chemoenzymatic strategy to afford a series of new analogs of parthenolide functionalized at the aliphatic positions C9 and C14. Several of these compounds were determined to be able to kill leukemia cells and patient-derived primary AML specimens with improved activity compared to parthenolide, exhibiting LC50 values in the low micromolar range. These studies demonstrate that different O-H functionalization chemistries can be applied to elaborate the parthenolide scaffold and that modifications at the C9 or C14 position can effectively enhance the antileukemic properties of this natural product. The C9-functionalized analogs 22a and 25b were identified as the most interesting compounds in terms of antileukemic potency and selectivity toward AML versus healthy blood cells.

Cytokine-induced killer cells combined with dendritic cells inhibited liver cancer cells.

OBJECTIVES: To investigate the prognosis of advanced liver cancer patients treated with CIK-DCs and the mechanism of apoptosis of HEPG 2 cells. METHODS: 67 patients were enrolled in the study. Peripheral blood mononuclear cells (PBMCs) were separated, of which adherent PBMCs used granulocyte 2 macrophage colony2 stimulating factor (GM2CSF), tumor necrosis factor 2α (TNF2α), and interleukin 24 (IL24) to induce DCs, which were sensitized with antigen of autologous or exogenous cancer cells to obtain Ag-DCs; suspended PBMCs used interferon 2γ (IFN2γ), IL-2, and CD 3 monoclonal antibody (CD3mAb) respectively, to induce CIK cells. DCs and CIK cells were cultured together. Flow cytometry was used to detect the phenotypes of DCs and CIK cells, and the blood retransfused into patients. Western blot and flow cytometer were used to analyze the growth cycle of HepG 2 cells and the expression of BAX and PCNA. RESULTS: No patients underwent complete remission, 5 obtained partial remission and 29 had stable disease. Of the 31 patients whose lesions could not be evaluated, 17 received effective treatment, showing that the immune response was enhanced. In vitro laboratory experiments revealed that DC-CIK cells markedly affected the growth cycle of HepG 2 cells. Analysis showed that DC-CIK cells enhanced the gene expression of BAX and inhibited the activity of PCNA. CONCLUSIONS: Co-cultured DCs and CIK cells inhibit the proliferation and migration of liver cancer cells by down-regulating PCNA and up-regulating BAX. This approach may be an effective method to treat advanced liver cancer.

[Therapeutic and adverse effects of topotecan combined with cisplatin for treatment of advanced squamous cell lung cancer and head and neck cancer].

OBJECTIVE: To evaluate the therapeutic and adverse effects of topotecan combined with cisplatin in the treatment of advanced squamous cell lung cancer and head and neck cancer. METHODS: Totally 126 patients with advanced squamous cell lung cancer and head and neck cancer, which were confirmed by tissue pathology or cytopathology, were treated with intravenous infusion of topotecan at the dose of 0.75-1.2 mg/m2 (for 5 consecutive days) combined with intravenous infusion of cisplantin at 25-30 mg/m2 for 3 consecutive days. Each treatment course consisted of two 21-day cycles of the treatment. RESULTS: No complete remission was achieved in these patients, and 61 patients had partial remission, 53 had clinically stabilized disease and 12 had progressive disease. The total response rate was 48.4% among the patients, with the median survival time of 10.1 months and one-year survival rate of 36.7%. The major adverse effects were bone marrow suppression and alopecia. CONCLUSION: Topotecan combined with cisplatin may achieve a favorable response in patients with advanced squamous cell lung cancer and head and neck cancer, and causes tolerable adverse effect without accumulative toxicity.