Zongyao Wen

Low viscosity Ektacytometry and its validation tested by flow chamber

The flow chamber was used to observe the orientation and small deformation of red blood cells (RBCs) in a shear flow of low viscosity. With the aid of computer software, the percentage of RBCs oriented to the C=0 orbit (OI)(F) and the degree of deformation (DI)(F) of such RBCs were calculated by processing the photographs. It was found that these parameters were highly correlated, respectively, to the orientation index (OI)(E) and the small deformation index (DI)(E) obtained by our low viscosity Ektacytometry (LVE). Thus, our flow chamber research has provided direct evidence to validate the use of this low viscosity Ektacytometry. Although there are relative merits for the flow chamber method using low viscosity medium, the LVE is more likely to be applied in clinic for its simplicity and convenience.

Effects of Gekko sulfated polysaccharide-protein complex on human hepatoma SMMC-7721 cells: inhibition of proliferation and migration.

AIM OF THE STUDY Gekko swinhonis Guenther has been used as an anti-cancer drug in traditional Chinese medicine for hundreds of years. Here we investigated the structural characterization and anti-cancer effects of sulfated polysaccharide-protein complex (GSPP) isolated from Gekko swinhonis Guenther. MATERIALS AND METHODS The structure of GSPP was characterized by high performance liquid chromatography, gas chromatography, gas chromatography-mass spectrometry, beta-elimination reaction, and NMR spectroscopy. SMMC-7721 cells were used to assess the influence of GSPP on hepatocellular carcinoma. Cell proliferation and survival was determined by trypan blue exclusion assay. Cell migration was performed by wound-healing and transwell assay. The secretion of IL-8 was detected by an enzyme-linked immunosorbent assay kit. Flow cytometry was used to analyze intracellular calcium concentration, as well as cell cycle distribution and apoptosis. Confocal microscopy was used to assess the localization and configuration of actin filaments. RESULTS GSPP was chemically characterized as a sulfated polysaccharide-protein complex with O-glycopeptide linkages. Our results showed that GSPP inhibited the proliferation of SMMC-7721 cells and blocked cells in the S phase. No direct toxicity against cells was observed. Furthermore, GSPP inhibited the migration of SMMC-7721 cells with the reduction of intracellular calcium. Actin filaments were polymerized and accumulated in the cytoplasm of the treated cells, whereas the secretion of IL-8 was not significantly changed after GSPP exposure. CONCLUSION We describe an identified sulfated polysaccharide-protein complex, and demonstrate its direct effect on hepatocellular carcinoma cell migration via calcium-mediated regulation of the actin cytoskeleton reorganization.

Effects of Gekko Sulfated Polysaccharide-Protein Complex on the Defective Biorheological Characters of Dendritic Cells Under Tumor Microenvironment

We previously isolated a sulfated polysaccharide–protein complex from Gekko swinhonis Guenther, a traditional Chinese medicine, and have demonstrated its direct anti-cancer effect on human hepatocellular carcinoma cell line SMMC-7721. Here we investigated the effects of Gekko sulfated polysaccharide–protein complex (GSPP) on the defective biorheological characters of dendritic cells (DCs) under SMMC-7721 microenvironment. Our findings have shown that the biorheological properties of DCs were severely impaired by SMMC-7721 microenvironment, including decreased cell deformability, migration, and electrophoresis mobility, increased osmotic fragilities, and changed organizations of cytoskeletal proteins. We also found decreased secretion of interleukin (IL)-12 and increased secretion of IL-10 in DCs. However, supernatant collected from nonmalignant liver cells had no effect on these parameters. SMMC-7721 cells were treated with GSPP and the supernatant was used to culture DCs. We found that the defective biorheological parameters of DCs, except for osmotic fragility, were partially or completely improved. The secretion of IL-12 did not change as compared with that of DCs in SMMC-7721 microenvironment, but the secretion of IL-10 was resumed to the control level. Our results indicate that GSPP could partially restore the defective biorheological characteristics of DCs via modifying the tumor microenvironment and decreasing the secretion of IL-10 of DCs.

TFAR19 gene changes the biophysical properties of murine erythroleukemia cells

TFAR19 is a novel apoptosis-related gene and can accelerate cell apoptosis in the presence of apoptosis inducements. Here, we studied the effects of TFAR19 on some biophysical properties of mouse erythroleukemia (MEL) cells and their molecular and structural basis. After transfected with TFAR19 and apoptosis, inducement, MEL revealed a high cell membrane fluidity, a decrease in resynthesis of phospholipids, an increase in the proteins/nucleic acids ratio, a relatively orderly cytoskeleton network, an impaired deformability, a low integrin aM expression, and a decrease in adhesion to endothelial cells. These findings suggest the potential of TFAR19 for antitumor cell migration, and thus for antitumor gene therapy.

Acute dichlorvos poisoning induces hemorheological abnormalities in rabbits via oxidative stress

Dichlorvos is an important insecticide used largely. Some studies have demonstrated that organophosphate pesticide has effects on erythrocyte membrane structures, which is critical to erythrocyte function and hemorheology. The aim of the present study was to explore the effect of oxidative stress on hemorheological changes during dichlorvos poisoning in rabbits. Data indicated that after dichlorvos exposure the hematocrit adjusted viscosity at high shear rate increased and erythrocyte membrane fluidity decreased. Data obtained from plasma showed that lipid peroxidative substance-malonaldehyde was elevated and superoxide dismutase was reduced. In summary, oxidative stress does occur in dichlorvos poisoning and may lead to hemorheological alterations. The changes of hemorheology may be responsible for the pathophysiology of the dichlorvos poisoning.

Biophysical studies on the differentiation of human CD14+ monocytes into dendritic cells.

Dendritic cells (DCs), which are the most efficient antigen-presenting cells (APCs) currently known, can be derived from CD14+ monocytes (DC predecessor cells) in vitro. Immature DCs actively take up antigens and pathogens, generate major histocompatability complex-peptide complexes, and migrate from the sites of antigen acquisition to secondary lymphoid organs to become mature dendritic cells that interact with and stimulate T-lymphocytes. During this process, the cells must undergo deformation to translocate through several barriers, including the basement membrane and interstitial connective tissue in the blood vessel wall. To further understand the mechanisms of the activation of immunological responses and the migration from peripheral tissue to secondary lymphoid organs, we have applied biophysical and microrheological methods to study the development processes of DCs in vitro. The results showed that membrane fluidity, osmotic fragility, membrane viscoelastic properties, infrared spectroscopy, and cytoskeleton organization of DCs exhibit significant differences in different developmental stages.

Hepatocellular Carcinoma Cells Deteriorate the Biophysical Properties of Dendritic Cells

Dendritic cells (DCs) are potent antigen-presenting cells and induce antigen-specific immune responses in the organism. The dysfunction of DCs has been implicated in tumor-bearing host. In order to elucidate the effects of tumor microenvironment on the functions of DCs from interdisciplinary aspects, we characterized the biophysical properties of DCs co-cultured with hepatocellular carcinoma cells (HCC). The results showed that the biophysical characteristics of immature and mature DCs were severely impaired by HCC compared with those under normal conditions, including the increased osmotic fragilities, decreased cell membrane fluidities, increased membrane viscoelastic properties, dysfunction and increased expression of cytoskeleton protein F-actin, as well as the deteriorated transendothelium migration. The impaired biophysical properties of DCs may be one of many aspects of the immune escape mechanisms of tumors. These results are clinically and instructionally significant with regard to how to enhance efficiency of the anti-tumor therapy based on DCs.

Influence of TRAIL gene on biomechanical properties of the human leukemic cell line Jurkat

We cloned the cDNA fragment of human TNF-related apoptosis inducing ligand (TRAIL) into RevTet-On, a Tet-regulated and high-level gene expression system. Making use of the TRAIL gene expression system in Jurkat as a cell model, we studied the influence of TRAIL gene on the biomechanics properties of Jurkat through measuring changes of cellular biomechanics properties before and after the TRAIL gene expression, which was induced by adding tetracycline derivative doxycycline (Dox). The results indicated that the TRAIL gene expression led to significant changes in cellular biomechanics properties. The osmotic fragility increased and the cell stiffness increased after the expression of TRAIL gene. Thus, the apoptosis-inducing TRAIL gene caused significant changes in the biomechanics properties of Jurkat cells.

Knockdown of hTERT Alters Biophysical Properties of K562 Cells Resulting in Decreased Migration Rate In Vitro

It has been shown that 90% of tumors, including hematological malignant tumors and leukemia, have much higher levels of telomerase expression than normal cells. To investigate the effect of telomerase on leukemia cells, we transfected K562, a human erythroleukemia cell line with an antisense-hTERT (human telomerase reverse transcriptase) cDNA vector, and examined the biological and biophysical properties of the stably transfected cells (referred to as KAT). Un-transfected cells (K562) and cells transfected with the empty vector (referred to as KC) were used as controls. Cell growth curve and 3H-TdR test showed that the growth rate and DNA synthesis of KAT decreased compared with those of K562 and KC cells. Apoptosis and cell cycle distribution in KAT cells under normal culture condition were similar to those of K562 and KC cells, but changed after serum deprivation. KAT cells had significantly different biophysical characteristics from K562 and KC in terms of cell electrophoresis, membrane fluidity, membrane fluidity, and viscoelasticity. Furthermore, the transendothelial migration rate of KAT was much lower than those of K562 and KC cells. Confocal microscopy showed that KAT cells had higher F-actin content, suggesting the reorganization of cytoskeleton. Flow cytometry analysis revealed a lowered intracellular calcium concentration and CD71 expression, explaining the high F-actin content in KAT cells. In conclusion, we found that the knockdown of hTERT in K562 cells changed their cytoskeleton and biophysical features, and reduced the cell migration.

BIOPHYSICAL MEANINGS OF ORIENTATION AND DEFORMATION OF RBCS IN SHEAR FLOW FIELD OF LOW VISCOSITY WITH NEW EKTACYTOMETRY

The rheological behavior of RBCs treated with WGA of different concentrations was measured by the recently developed new Ektacytometry method in suspending medium of low viscosity. The biophysical meanings of the orientation index (DI)or and the small deformation index (DI)d in the new Ektacytometry were explained by comparison with the results using the fluorescence polarization technique and the electron spin resonance technique (ESR).