【Abstract】Objective To construct a recombinant adenoviral vector carrying antisense matrix metalloproteinase2 (MMP2) for use in the gene therapy to inhibit the invasiveness and migratory capacity of hepatocellular carcinoma (HCC) cell line HepG2 in vitro and in vivo models. Methods Total RNA was extracted from HCC, and then a 500 bp fragment at the 5′ end of human MMP2 cDNA was synthesized by polymerase chain reaction (PCR) and was reversely inserted into the multiclone site (MCS) of the shuttle plasmid pAdTrack-CMV,with the resultant plasmid and the backbone plasmid pAdEasy-1,the homologous recombination took place in the E.coli BJ5183 and the recombinant adenoviral plasmid carrying the antisense MMP2 gene was constructed and generated. The adenoviruses(Ad-MMP2AS) were packaged and amplified in the HEK 293 cells.Then the viral titer was checked by GFP. Results The recombinant adenovirus vector carrying antisense MMP2 was constructed successfully, the b green fluorescence was observed in HEK 293 cells under a fluorescence microscopy. The viral titer was 1×108/ml. Conclusion The recombinant adenovirus Ad-MMP2AS constructed by us could introduce the antisense MMP2 into HepG2 effectively,which would provide experimental basis for reversing the overexpression of MMP2 in HCC and for inhibiting the invasiveness and migratory capacity of HepG2 in vitro and in vivo models.
Objective Col I A1 antisense oligodeoxyneucleotide (ASODN) has inhibitory effect on collagen synthesis in cultured human hypertrophic scar fibroblasts. To investigate the effects of intralesional injection of Col I A1 ASODN on collagen synthesis in human hypertrophic scar transplanted nude mouse model. Methods The animal model of humanhypertrophic scar transplantation was established in the 60 BALB/c-nunu nude mice (specific pathogen free grade, weighing about 20 g, and aged 6-8 weeks) by transplanting hypertrophic scar without epidermis donated by the patients into the interscapular subcutaneous region on the back, with 1 piece each mouse. Fifty-eight succeed models mice were randomly divided into 3 groups in accordance with the contents of injection. In group A (n=20): 5 μL Col I A1 ASODN (3 mmol/L), 3 μL l iposome, and 92 μL Opti-MEM I; in group B (n=20): 3 μL l iposome and 97 μL Opti-MEM I; in group C (n=18): only 100 μL Opti-MEM I. The injection was every day in the first 2 weeks and once every other day thereafter. The scar specimens were harvested at 2, 4, and 6 weeks after injection, respectively and the hardness of the scar tissue was measured. The collagens type I and III in the scar were observed under polarized l ight microscope after sirius red staining. The ultrastructures of the scar tissues were also observed under transmission electronic microscope (TEM). Additionally, the Col I A1 mRNAs expression was determined by RT-PCR and the concentrations of Col I A1 protein were measured with ELISA method. Results Seventeen mice died after intralesional injection. Totally 40 specimens out of 41 mice were suitable for nucleic acid and protein study, including 14 in group A, 13 in group B, and 14 in group C. The hardness of scars showed no significant difference (P gt; 0.05) among 3 groups at 2 weeks after injection, whereas the hardness of scars in group A was significantly lower than those in groups B and C at 4 and 6 weeks (P lt; 0.05), and there was no significant difference between groups B and C (P gt; 0.05). The collagen staining showed the increase of collagentype III in all groups, especially in group A with a regular arrangement of collagen type I fibers. TEM observation indicated that there was degeneration of fibroblasts and better organization of collagen fibers in group A, and the structures of collagen fibers in all groups became orderly with time. The relative expressions of Col I A1 mRNA and the concentrations of Col I A1 protein at 2 and 4 weeks after injection were significant difference among 3 groups (P lt; 0.05), and they were significantly lower in group A than in groups B and C (P lt; 0.05) at 6 weeks after injection, but no significant difference was found between groups B and C (P gt; 0.05). Conclusion Intralesional injection of Col I A1 ASODN in the nude mice model with human hypertrophic scars can inhibit the expression of Col I A1 mRNA and collagen type I, which enhances the mature and softening of the scar tissue. In this process, l iposome shows some assistant effect.
Objective To study the effects of glutaminase (GA) gene blocked by antisense nucleotide on apoptosis of transplanted gastric carcinoma cells in nude mice. Methods The plasmid containing antisense sequence of GA gene was trans-fected into gastric carcinoma cells , then the cells were injected to endermic tissue of nude mice to create animal models of gastric carcinoma. Apoptosis of tumor cells was detected by terminal deoxynucleotidyl transferase2mediated nick end labeling (TUNEL) method. The expression of GA mRNA in tumor tissue was measured by reverse transcription polymerase chain reaction (RT2PCR) technique. Results After the successful transfection of plasmid containing antisense sequence of GA gene into gastric carcinoma cells , the tumor’s growth speed decreased , apoptosis of tumor cells increased , and the expression of GA mRNA also decreased. Conclusion The antisense gene of GA could inhibit the expression of GA gene and significantly increase the apoptosis of gastric carcinoma cells.
Objective To observe the inhibitory effects of local co-transfection of tissuetype plasminogen activator(tPA) gene and proliferating cell nuclear antigen antisense oligodeoxynucleotides(PCNA-ASODN) on the intima proliferation and restenosis of autograft artery in rabbits. Methods One hundred and twenty male Zelanian rabbits were randomly divided into four groups(n=30, in each group): control group, PCNA-ASODN group, tPA group and tPA+PCNAASODN group. The left and right external iliac arteries (length 1.0 cm) were transplanted reciprocally. The transplanted arteries were respectively soaked in lipofection, PCNAASODN, pBudCE4.1/tPA and pBudCE4.1/tPA+PCNA-ASODN solution about 15 minutes. The transplanted arteries were sutured with 9-0 sutures soaked in PCNA-ASODN and pBudCE4.1/tPA solution. Each group were divided into five subgroups(n=6, in each subgroup) according to the sacrifice time (3 d, 7 d, 14 d, 28 d and 56 d after operation). On every sacrifice time point, the vascular specimens were harvested. The thrombocyte assembling and thrombus forming lining vessel wall were observed by scanning electron microscope. The pathological morphology of transplanted arteries were observed under microscope(HE). The intimal areas and stenosis ratio(%) of transplanted arteries were calculate and analyzed statistically among groups by computer system. The mRNA expression of tPA gene in transplanted ressel wall was detected with vevere transcriptionPCR(RT-PCR). The number of PCNA positive cells in transplanted vessel wall was counted by SP immunochemisty.Results The mRNA expression of tPA gene in the transplanted vessel wall in tPA and tPA+PCNA-ASODN groups was higher than that of the other two groups(P<0.01).The number of PCNA positive cells in the transplanted arteries in PCNAASODN, tPA and tPA+PCNAASODN groups were significantly lower than that of control group(P<0.05,P<0.01). The intimal areas and degrees of luminal stenosis of PCNAASODN, tPA and tPA+PCNAASODN groups were lower than those of control group(P<0.05,P<0.01), and those of tPA+ PCNA-ASODN group were lower than those of PCNA-ASODN and tPA groups(P<0.05). Scanning electron microscopy showed that there were a few thrombocytes lining the vessel wall of tPA group and tPA+PCNAASODN group and no thrombus, whereas there were abundant thrombocytes and thrombi lining the vessel wall of the control group. Conclusion Co-transfection of tPA gene and PCNA-ASODN can effectively inhibit the proliferation of VSMC, hyperplasia of intima and restenosis of transplanted artery.
Objective To study the effects on MCF-7 breast cancer cells with combination of tamoxifen(TAM) and antisense oligonucleotide (ASODN) targeting survivin mRNA. Methods MCF-7 breast cancer cells were treated with a 20 mer ASODN targeting survivin mRNA and TAM, which were divided into three groups: TAM group (treated by TAM only), ASODN group (by ASODN only), and TAM+ASODN combined group (by TAM+ASODN combination). The growth inhibition of MCF-7 cells, the changes of cell cycles and apoptotic rate, the positive rate of survivin mRNA expression, and the activity of caspase-3 were tested by MTT, flow cytometry, hybridization in situ, and spectrophotometric method, respectively.Results The rate of growth inhibition of MCF-7 cells in the TAM+ASODN combined group was (62.26±3.92)%, which was significantly higher than that in the TAM group 〔(42.30±6.63)%〕 or ASODN group 〔(54.77±9.99)%〕, Plt;0.05. The apoptotic rate of MCF-7 cells was (28.08±4.32)% in the TAM+ASODN combined group, which was significantly higher than that in the TAM group 〔(18.94±4.01)%〕 or ASODN group 〔(21.12±3.95)%〕, Plt;0.01. The effect of arresting MCF-7 cells in G0/G1 phase in the TAM+ASODN combined group was ber than that in the TAM or ASODN group (Plt;0.05, Plt;0.01). The positive rate of survivin mRNA in the TAM+ASODN combined group was (13.38±3.45)%, which was significantly lower than that in the TAM group 〔(39.67±7.42)%〕 or ASODN group 〔(27.50±5.80)%〕, Plt;0.01. The activity of caspase-3 in the TAM+ASODN combined group (0.93±0.13) was significantly higher than that in the TAM group (0.50±0.09) or ASODN group (0.64±0.08), Plt;0.01. Conclusion The ASODN targeting survivin mRNA can promote the apoptosis of MCF-7 breast cancer cells, and make MCF-7 cells more sensitive to tamoxifen.
Objective To investigate the reversal effect of antisense phosphorothioate oligonucleotide (ASOND) on human hepatoma resistant cells. Methods Human hepatoma resistant cells SMMC-7721 was transfected with synthetic antisense phosphorothioate oligonucleotide complementary to the 5′ region flanking the AUG initiation codon mediated by lipofectamine. In vitro drug sensitivity was measured by MTT assay. The expression of P-170 was determined by flow cytometry and mRNA was assessed by RT-PCR. Results ASOND inhibited the expression of mRNA and p-170 in SMMC-7721, enhanced the sensitivity of SMMC-7721 to chemotherapeutic drug. The best inhibitory effect was achived by the dose of 0.5μmol/L. Conclusion ASOND enhanced the sensitivity of SMMC-7721 to chemotherapeutic drug and reversed the multidrug resistance of SMMC-7721 partially.
Objective To investigate an inhibitive effect of the chitosan nanoparticles with the proliferation cell nuclear antigen (PCNA)-antisense oligo deoxy nucleotides (ASODN) on the intimal cell proliferation after the vein grafting.Methods Fiftyfour male SD rats, weighing 450-600g, were randomly divided in the experimental group and the control group of 27 rats each. In the experimental group, the chitosan nanoparticles with PCNAASODN were infused into the anastomosis segment of the right jugular artery and vein; then, the anastomosis segment was transplanted to the jugular artery on the same side. The rats in the control group were infused with normal saline by the same procedures. There were 24 rats in each group which used to experiment. The hemodynamic data were obtained from the Doppler ultrasound examinations at 1, 2, 3 and 4 weeks. The specimens were taken. Immunohistochemistry, Westernblot, and bloodvesselwall histopathology were performed at the different week points. Results There was no significant difference in the thrombogenesis rate between the experimental group and the control group (3/27 vs. 3/27,P>0.05). During the 4 week observation, PCNA Westernblot showed that the PCNA level was lower in the grafted vein and the anastomosis segment in the experimental group than in the control group. The indexes of the PCNA postive proliferating cells in the intimal area (0.13%±0.11%,0.79%±0.28%,0.45%±0.29%, 0.43%±0.25%) and the medial area (1.90%± 0.84%,2.11%±0.98%,2.48%±0.77%,2.17%±0.36%) were significantlydecreased at 1,2,3 and 4 weeks in the experimental group when compared with those in the control group(P<0.05). The lumen areas in the grafted vein (88.71±16.96,95.98±21.44,88.48±32.81,97.86±34.11 μm 2) and the anastomosis segment (41.49±3.34,45.15±11.65,46.27±8.90,51.62±8.85 μm 2) were significantly greater in the experimental group than in the control group (P<0.05). The ratios of the initmal area to the medial area in the grafted vein (22.73%±3.11%,32.40%±4.55%,45.14%±3.19%,45.70%±5.01%) and the anastomsis segment (41.49%±3.34%,45.15%±11.65%,46.27%±890%,51.62%±8.85%) were significantly smaller in the experimental group than in the control group(P<0.05). The maximum velocities (Vmax) of the blood flow inthe grafted vein and the anastomsis segment were almost the same in the two groups at 1 week, but had different changes at the next 3 weekpoints. In the control group, the Vmax of the blood flow gradually increased and at 3 weeks it reached the peak point; however, at 4 weeks it decreased. In the experimental group,the Vmax of the blood flow gradually decreased, and at 3 weeks it decreased to the lowest point; however, at 4 weeks it increased. So, at 4 weeks the Vmax of the blood flow in the grafted vein and the anastomsis segment was almost the samein the two groups. There was no significant difference in the Vmax of the bloodflow between the two groups (P>0.05), but in the same group there wasa significant difference at the different time points. Conclusion The chitosan nanoparticles with PCNAASODN can effectively inhibit the intimal cell proliferation after the grafting of the blood vessel, so that the neointimal thickening can be prevented.
To investigate the inhibitory effect of Col I A1 antisense ol igodeoxyneucleotide (ASODN) transfection mediated by cationic l iposome on Col I A1 expression in human hypertrophic scar fibroblasts. Methods Scar tissue was obtained from volunteer donor. Human hypertrophic scar fibroblasts were cultured by tissue block method. The cells at passage 4 were seeded in a 6 well cell culture plate at 32.25 × 104 cells/well, and then divided into 4 groups: group A, l iposomeand Col I A1 ASODN; group B, Col I A1 ASODN; group C, l iposome; group D, blank control. At 8 hours, 1, 2, 3 and 4 days after transfection, total RNA of the cells were extracted, the expression level of Col I A1 mRNA was detected by RT-PCR, the Col I A1 protein in ECM was extracted by pepsin-digestion method, its concentration was detected by ELISA method. Results Agarose gel electrophoresis detection of ampl ified products showed clear bands without occurrence of indistinct band, obvious primer dimmer and tailing phenomenon. Relative expression level of Col I A1 mRNA: at 8 hours after transfection, group A was less than groups B, C and D (P lt; 0.05), and groups B and C were less than group D (P lt; 0.05), and no significant difference was evident between group B and group C (Pgt; 0.05); at 1 day after transfection, groups A and B were less than groups C and D (P lt; 0.05), and there was no significant difference between group A and group B, and between group C and group D (P gt; 0.05 ); at 2 days after transfection, there were significant differences among four groups (P lt; 0.05); at 3 and 4 days after transfection, group A was less than groups B, C and D (P lt; 0.05), group B was less than groups C and D (P lt; 0.05), and no significant difference was evident between group C and group D (P gt; 0.05). Concentration of Col I protein: at 8 hours after transfection, group A was less than groups B, C and D (P lt; 0.05), groups B and C were less than group D (P lt; 0.05), and no significant difference was evident between group B and group C (P gt; 0.05); at 1 day after transfection, significant differences were evident among four groups (P lt; 0.05); at 2, 3 and 4 days after tranfection, groups A and B were less than groups C and D (P lt; 0.05), and no significant difference was evident between group A and group B (P gt; 0.05). Conclusion Col I A1 ASODN can inhibit mRNA and protein expression level of Col I A1. Cationic l iposome, as the carrier, can enhance the inhibition by facil itating the entry of ASODN into cells and introducing ASODN into cell nucleus.
【Abstract】ObjectiveTo study the apoptosis of gallbladder carcinoma cell line GBCSD induced by antisense oligodeoxynucleotide (ASODN) targeting survivin. MethodsASODN targeting survivin was transfected into GBCSD cells mediated by lipofectin. Cultured cells were divided into 3 groups: control group,sense oligonucleotide (SODN) group and ASODN group. After transfected for 16 h, the cultured cells were harvested and the following texts were carried out. The expression of survivin mRNA was detected by RTPCR. Flow cytometer were used to detect apoptosis. Morphological changes were observed by electron microscopy. ResultsThe expression of survivin mRNA was decreased 47.83% in ASODN group while apoptosis was increased from (0.50±0.23)% to (26.28±3.91)%. Abnormal morphological changes of cells were observed in ASODN group and apoptosis bodies were found in some gallbladder carcinoma cells. ConclusionThe expression of survivin may be decreased in GBCSD cells after ASODN transfection.ASODN targeting survivin could induce gallbladder carcinoma cells apoptosis effectively.
Objective To investigate the inhibitory effect of survivin antisense oligonucleotides (ASODN) on proliferation of pancreatic cancer cells PANC-1. Methods The ASODN and sense oligodeoxynucleotides (SODN) were complementary to survivin sequences. FAM-marked ASODN was transfected into PANC-1 cells mediated by positive ion liposome as ASODN group. Blank control group (normal cells), negative control group (normal medium), and SODN group were established for comparison. The transfection efficiency was detected by flow cytometry (FCM) after transfection; MTT assay was used to detect cytotoxicity; Cell morphological changes were examined by transmission electron microscopy; The cell cycle and apoptotic rate were analyzed by FCM; Immunohistochemical staining techniques were used, and the expressions of survivin were observed under light microscopy, examined and analysed by computer image. Results ①The transfection efficiency was 31.9%, 37.4%, 41.4%, 52.6%, 24.2%, 11.4%, 16.1%, and 15.5% when the transfecting concentration of ASODN was 50, 100, 150, 200, 250, 400, 600, and 800 nmol/L, respectively; The transfection efficiency was 12.0%, 50.8%, and 11.2% when the inoculated cells was 2×104/well, 2×105/well, and 2×106/well, respectively; The transfection efficiency was 58.8%, 34.0%, and 23.6% when 2 μl, 3 μl, and 4 μl liposome was used during transfection, respectively. ②Cell gap was oversize, morphous was round, adherent cells were less after transfection under fluorescence microscope. ③The inhibition rate in the ASODN group was higher than that in each control group (Plt;0.05) on 24, 36, 48 h after treating by survivin ASODN, which increased as time prolonged (Plt;0.05). ④The apoptosis showed a ladder-shaped line in the ASODN group. ⑤Apoptotic morphology was demonstrated in the ASODN group, such as apoptotic cells with nuclear chromatin highly concentrated, crescent nuclear staining aggregated by the side nuclear membrane, nucleolus disappeared by AO and EB stains. ⑥The apoptotic rate 〔(38.1±3.4)%〕 in the ASODN group was higher than that in the SODN group 〔(4.16±1.7)%〕, Plt;0.05. ⑦G2/M cell cycle arrested in the ASODN group. ⑧After transfection, the expression of survivin protein in the ASODN group was significantly lower than that of each control group (Plt;0.05). Conclusions The optimal transfection conditions are as following: the cell count of 2×105/well, concentration of ASODN 200 nmol/L, and cationic liposome oligofectamine 2 μl, respectively. Survivin ASODN can inhibit the proliferation of pancreatic cancer cells and induce their apoptosis.
