No abstract available.
Brain Neoplasms* ; Brain* ; Cell Line* ; Immunotoxins*

Dendritic cells (DCs) as a rare type of leukocytes play an important role in bridging the innate and adaptive immune system. A subset of DCs, monocyte-derived dendritic cells (moDCs), exists in very low numbers at steady state but become abundant in inflammatory states. These inflammation-associated DCs are potent producers of pro-inflammatory cytokines and potent inducers of T helper differentiation. They behave as a "double-edge" sword so that they not only mediate protective immunity but also immuno-pathology. It is still incompletely understood how their function is regulated. Emerging evidence indicates that microRNAs (miRNAs), as a new class of gene regulators, potently regulate the function of moDCs. Here we summarize recent progress in this area.
Animals ; Antigen Presentation ; genetics ; Cell Differentiation ; Cytokines ; genetics ; metabolism ; Dendritic Cells ; metabolism ; physiology ; Humans ; Inflammation ; immunology ; pathology ; MicroRNAs ; metabolism ; physiology ; RNA Interference

A new approach to enhancing the effectiveness of vaccines is to deliver antigens selectively to dendritic cells (DC) in situ, via monoclonal antibodies specific for particular DC surface molecules. This can markedly enhance CTL responses and, via helper T cells, also enhance antibody responses. DC activation agents or adjuvants must also be administered for effective CTL responses, but in some cases good antibody responses can be obtained without adjuvants. Here we review the role of different DC subsets and different DC target molecules in obtaining enhanced immune responses.
Antibodies, Monoclonal/immunology ; Antibody Formation ; Antigens/*administration & dosage/immunology ; Dendritic Cells/cytology/*immunology ; Humans ; Vaccines/*immunology

A new approach to enhancing the effectiveness of vaccines is to deliver antigens selectively to dendritic cells (DC) in situ, via monoclonal antibodies specific for particular DC surface molecules. This can markedly enhance CTL responses and, via helper T cells, also enhance antibody responses. DC activation agents or adjuvants must also be administered for effective CTL responses, but in some cases good antibody responses can be obtained without adjuvants. Here we review the role of different DC subsets and different DC target molecules in obtaining enhanced immune responses.
Antibodies, Monoclonal/immunology ; Antibody Formation ; Antigens/*administration & dosage/immunology ; Dendritic Cells/cytology/*immunology ; Humans ; Vaccines/*immunology

The pathways leading to the development of different dendritic cell (DC) subsets have long been unclear. In recent years, a number of precursors on the route to DC development, both under steady state and inflammatory conditions, have been described, and the nature of these pathways is becoming clearer. In addition, the development of various knockout mouse models and an in vitro system modelling DC development have revealed the role of numerous cytokines and transcription factors that influence DC development. Here, we review recent findings on the factors important in DC development in the context of the developmental pathways that have been described.
Animals ; Cytokines ; metabolism ; Dendritic Cells ; metabolism ; Humans ; Signal Transduction ; physiology ; Transcription Factors ; metabolism

OBJECTIVE: To investigate the in vitro and in vivo anticancer efficacy of the immunotoxin DTATEGF against human NSCLC brain metastatic tumor PC9-BrM3 cell line. METHODS: The effect of the immunotoxin DTATEGF was tested for its ability to inhibit the proliferation of PC9-BrM3 cells in vitro by MTT assay. The cell cycle and the apoptosis of cells with 1 pmol/L DTATEGF were examined by flow cytometry. In vivo, 2 μg of DTATEGF or control Bickel3 was given intratumor to nude mice with established PC9-BrM3 xenografts on their hips, and tumor volumes were measured and tumor samples were investigated by immunchistochemistry SABC method. The microvessel density (MVD) was measured in each group. RESULTS: In vitro, DTATEGF killed PC9-BrM3 cells and showed an IC50 of 1 pmol/L. The apoptotic rate in the 1 pmol/L DTATEGF group was (64.0±0.5)% , significantly higher than that in the control group (1.5±0.4)% (P<0.01). The cell cycle was obviously inhibited by DTATEGF in a dose-dependent manner. The percentage of cells treated with 1 pmol/L DTATEGF in SubG0/G1 phase was (32.0±1.5)%, significantly higher than that in the control group (2.0±0.4)% (P<0.01). In vivo, DTATEGF significantly inhibited the growth of PC9-BrM3 hip tumors (P<0.05). The MVD of the DTATEGF group was (15.6±4.6)/mm2, significantly lower than that of the control group (31.2±5.4)/mm2 (P<0.01). CONCLUSION DTATEGF inhibits the growth of the PC9-BrM3 cell line and induces its apoptosis. It is highly efficacious against human metastatic NSCLC brain tumor and against neovascularization.
Animals ; Antibodies, Bispecific ; pharmacology ; Apoptosis ; Brain Neoplasms ; drug therapy ; Carcinoma, Non-Small-Cell Lung ; drug therapy ; Cell Cycle ; Cell Line, Tumor ; Humans ; Immunotoxins ; pharmacology ; Mice ; Mice, Nude ; Neovascularization, Pathologic ; prevention & control ; Xenograft Model Antitumor Assays

OBJECTIVE: To investigate the in vitro and in vivo anticancer efficacy of the immunotoxin DTAT and DTATEGF against globlastoma multiforme. METHODS: The in vitro cytotoxicity of DTAT and DTATEGF was measured using MTT assay. In vivo studies were performed in which 18 nude mice were randomly divided into 3 groups and the glioma xenograft intracranial mouse model was constructed with U87-luc cell line of human glioma. Then 1 μg of DTAT, or DTATEGF, or a control protein Bickel3 was delivered intracranially by convection-enhanced delivery (CED) via an osmotic minipump. The brain tumor fluorescence signal intensity was investigated by bioluminescent imaging (BLI). Microvessel density (MVD) was measured by immunchistochemistry SABC method in each group. RESULTS: In vitro DTAT and DTATEGF were found highly potent against U87-luc cell line, with IC(50) <0.01 nmol/L and IC(50)<1 nmol/L, respectively. In vivo BLI monitoring of the control group showed progressively increasing luminescence, while in the two treatment groups, luminescence was reduced on day 8, and increased slowly (P<0.05). The MVD of DTAT (31.6±5.2)/mm(2) and DTATEGF (25.1±6.5)/mm(2) groups had significant difference with that of the control group (51.3±7.4) /mm(2) (P<0.01). CONCLUSION Both DTAT and DTATEGF have potential in clinical application against globlastoma multiforme because of their ability to target the tumor cells and neovasculature simultaneously.
Angiogenesis Inhibitors ; pharmacology ; Animals ; Brain Neoplasms ; drug therapy ; Cell Line, Tumor ; Glioblastoma ; drug therapy ; Glioma ; Humans ; Immunotoxins ; pharmacology ; Mice ; Mice, Nude ; Xenograft Model Antitumor Assays

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection can cause acute respiratory distress syndrome, hypercoagulability, hypertension, and multiorgan dysfunction. Effective antivirals with safe clinical profile are urgently needed to improve the overall prognosis. In an analysis of a randomly collected cohort of 124 patients with COVID-19, we found that hypercoagulability as indicated by elevated concentrations of D-dimers was associated with disease severity. By virtual screening of a U.S. FDA approved drug library, we identified an anticoagulation agent dipyridamole (DIP) , which suppressed SARS-CoV-2 replication . In a proof-of-concept trial involving 31 patients with COVID-19, DIP supplementation was associated with significantly decreased concentrations of D-dimers ( < 0.05), increased lymphocyte and platelet recovery in the circulation, and markedly improved clinical outcomes in comparison to the control patients. In particular, all 8 of the DIP-treated severely ill patients showed remarkable improvement: 7 patients (87.5%) achieved clinical cure and were discharged from the hospitals while the remaining 1 patient (12.5%) was in clinical remission.