Strain-based genetic differences regulate the efficiency of systemic gene delivery as well as expression.

We have characterized the impact of strain-based genetic differences on the efficiency of the intravenous cationic liposome-DNA complex (CLDC)-based gene transfer and expression in mice. We also investigated what steps in the gene delivery and expression pathway appeared responsible for these strain-related differences and whether such differences could be compensated for either by agents that alter host pathways important in CLDC-mediated gene transfer and expression, or by changes in CLDC formulation. We found that different mouse strains can exhibit different expression levels and/or differences in the amount of plasmid DNA delivered to the organs where the DNA is expressed. Furthermore, drug pretreatment or reformulation of the CLDC could improve DNA delivery and/or gene expression in a strain-specific fashion. We conclude that genetic factors critically modify both the tissue deposition and the expression of genetic materials delivered by CLDC. Because manipulation of either the host or the CLDC could at least partially compensate for these strain-related differences, such strategies may be required to effectively use non-viral gene transfer approaches in genetically diverse populations.     

Evaluation of cationic liposome suitable for gene transfer into pregnant animals.

Cationic liposome-mediated in vivo gene transfer represents a promising approach for somatic gene therapy. To assess the most suitable liposome for gene delivery into a wide range of organs and fetuses in mice, we have explored several types of cationic liposomes conjugated with plasmid DNA carrying the beta-galactosidase gene through intravenous injection into pregnant animals. Transduction efficiency was assessed by Southern blot analysis and expression of the transferred gene was evaluated by enzymatic demonstration of beta-galactosidase activity. Through the analysis of several types of recently synthesized cationic liposome/lipid formulations, DMRIE-C reagent, a liposome formulation of the cationic lipid DMRIE (1, 2-dimyristyloxypropyl-3-dimethyl-hydroxy ethyl ammonium bromide) and cholesterol in membrane-filtered water met our requirements. When the plasmid DNA/DMRIE-C complexes were administered intravenously into pregnant mice at day 11.5 post coitus (p.c.), transferred genes were observed in several organs in dams and were expressed. Furthermore, although the copy numbers transferred into embryos were low, we observed reporter gene expression in the progeny.     

Lipid-DNA complexes induce potent activation of innate immune responses and antitumor activity when administered intravenously.

Cationic lipid-DNA complexes (CLDC) are reported to be safe and effective for systemic gene delivery, particularly to the lungs. However, we observed that i.v. injection of CLDC induced immunologic effects not previously reported. We found that even very low doses of CLDC administered i.v. induced marked systemic immune activation. This response included strong up-regulation of CD69 expression on multiple cell types and systemic release of high levels of Th1 cytokines, from both lung and spleen mononuclear cells. CLDC were much more potent immune activators on a per weight basis than either LPS or poly(I:C). The remarkable potency of CLDC appeared to result from enhancement of the immune stimulatory properties of DNA, since cationic lipids alone were without immune stimulatory activity. Systemic treatment with CLDC controlled tumor growth and significantly prolonged survival times in mice with metastatic pulmonary tumors. NK cells accumulated to high levels in the lungs of CLDC-treated mice, were functionally activated, and released high levels of IFN-gamma. The antitumor activity induced by CLDC injection was dependent on both NK cells and IFN-gamma. Thus, DNA complexed to cationic liposomes becomes highly immunostimulatory and capable of inducing strong antitumor activity when administered systemically.     

Liposome‐mediated DNA transfer to chicken sperm cells

Abstract

The efficacy of using liposomes to transfer DNA to chicken sperm cells was investigated. Liposomes were prepared from dilauroyl (12:0) phosphatidylcholine (DLPC), dimyristoyl (14:0) phosphatidyl choline (DMPC), dipalmitoyl (16:0) phosphatidylcholine (DPPC), egg yolk phosphatidylcholine (EYPC) or lipids extracted from sperm cell membranes. The efficiency of trapping of DNA into the liposomes, transfer of the DNA from the liposomes to the sperm cells and the effect of the liposomes on the fertilizing ability of the sperm cells were determined. Increasing the concentration of lipid in the liposome preparations increased the trapping efficiency of DNA into liposomes but lowered the transfer of DNA to sperm. Including stearylamine (SA) in the liposomes increased the incorporation of DNA into the liposomes and the DNA transfer to sperm cells, while including lauroyllysophosphatidylcholine (LPC) along with SA resulted in the highest transfer efficiency from liposomes to sperm. The transfer of DNA from liposomes to sperm cells was lowered by increasing the number of sperm cells, while decreasing the number of sperm cells lowered the fertility. The sperm cells remained fertile after exposure to low levels of DPPC or lipofectin reagent or to high levels of SA and LPC. The best conditions for liposome‐mediated gene transfer to chicken sperm cells are thus using either lipofectin reagent at .006 to .06 μmol/ml and 5 × 10⁷ sperm or with DPPC liposomes comprised of 10 μmol/ml total lipid including 5 mol% SA and 20 mol% LPC with 2.5 × 10⁸ sperm cells. The use of liposomes to enhance the transfer of DNA to sperm cells may make the use of sperm cells as gene transfer vectors possible.     

Incorporation of all-trans retinoic acid into lipoplexes inhibits nuclear factor kappaB activation mediated liver injury induced by lipoplexes in mice

BACKGROUND: All-trans retinoic acid (ATRA) is a natural derivative of vitamin A, which is well known to suppress inflammatory cytokine production. To date, there have been few reports about the systemic use of ATRA for inflammation because of acute resistance and the highly lipophilic nature of ATRA. METHODS: ATRA-lipoplexes were prepared by mixing CMV-Luc plasmid DNA with ATRA-incorporated 1,2-dioleoyl-3-trimethylammoniopropane (DOTAP)/cholesterol liposome. After intravenous injection, tissue accumulation, transfection efficacy, NFkappaB activation, cytokine production, and hepatic toxicity of ATRA-lipoplexes were evaluated and compared with lipoplexes lacking ATRA. RESULTS: The particle size and zeta potential of ATRA-lipoplexes were similar to those of lipoplexes. After intravenous injection of ATRA-lipoplexes, tissue accumulation in liver and gene expression in liver and lung were similar to those of lipoplexes, supporting the hypothesis that ATRA incorporation did not affect the delivery and gene transfection efficacy. In addition, ATRA incorporated in ATRA-lipoplexes was delivered to liver in a manner similar to that for ATRA incorporated in liposomes. In addition, intravenous injection of ATRA-lipoplexes inhibited the activation of NFkappaB in liver, and subsequently suppressed the serum levels of tumor necrosis factor-alpha (TNF-alpha) and alanine aminotransferase (ALT) compared with lipoplexes. Liver histology data also demonstrated a low degree of liver injury produced by ATRA-lipoplexes compared with lipoplexes. CONCLUSIONS: ATRA-incorporated lipoplexes effectively suppress NFkappaB activation, cytokine response and liver injury induced by lipoplexes without affecting gene delivery and transfection efficacy in vivo.     

Production of transgenic mice expressing the goat H-FABP gene by intratesticular injection

The objective of this study was to explore the possibility of obtaining stable transgenic animals by intratesticular injection. The recombinant vector pEGFP-H-FABP expressing the goat heart-type fatty acid binding protein and green fluorescent protein was mixed with liposome complexes and randomly injected into the testes of mice. Testicular section, fluorescence, and DNA detection assays of mouse sperm were performed to determine the integration of foreign DNA. The results showed that foreign DNA was successfully expressed in the treated mice. Furthermore, the expression and function of the foreign gene were analyzed in F₁ generation and F₂ generation mice at different levels, with the positive rates of foreign gene transfer into the F₁ and F₂ generations being 4.0 and 30.23 %, respectively. These results strongly support testicular injection as an effective method of producing transgenic animals and indicate that foreign genes can be stably passed on to the offspring. This research has theoretical and practical implications for the improvement in the quality of laboratory animals and for gene therapy.     

Use of lipoplex-induced nuclear factor-kappaB activation to enhance transgene expression by lipoplex in mouse lung

BACKGROUND: Although lipofection-induced TNF-alpha can activate nuclear factor kappaB (NF-kappaB), which, in turn, increases the transgene expression from plasmid DNA in which any NF-kappaB responsive element is incorporated, no attempts have been made to use such biological responses as NF-kappaB activation against a vector to enhance vector-mediated gene transfer. METHODS: A lipoplex composed of N-[1-(2,3-dioleyloxy)propyl]-N,N,N-trimethylammonium and cholesterol liposome and plasmid DNA encoding firefly luciferase under the control of the cytomegalovirus immediate early promoter (pCMV-Luc) was intravenously injected into mice. Luciferase activity as well as NF-kappaB activation in the lung were evaluated. Then, a novel plasmid DNA, pCMV-kappaB-Luc, was constructed by inserting 5 repeats of NF-kappaB-binding sequences into the pCMV-Luc. RESULTS: NF-kappaB in the lung was activated by injection of the lipoplex and its nuclear localization was observed. An injection of lipopolysaccharide 30 min prior to the lipofection further activated NF-kappaB. At the same time, the treatment significantly increased the transgene expression by lipoplex, suggesting a positive correlation between expression and NF-kappaB activity. Based on these findings, we tried to enhance the lipoplex-based transgene expression by using NF-kappaB activation. The lipoplex consisting of pCMV-kappaB-Luc showed a 4.7-fold increase in transgene expression in the lung compared with that with pCMV-Luc. CONCLUSIONS: We demonstrated that NF-kappaB activation by lipoplex can be used to enhance lipoplex-mediated transgene expression by inserting NF-kappaB-binding sequences into plasmid DNA. These findings offer a novel method for designing a vector for gene transfer in conjunction with biological responses to it.     

In vivo gene transfer using cetylated polyethylenimine

This report describes gene transfer in vitro as well as in vivo using cetylated low-molecular mass (600 Da) polyethylenimine (28% of amine groups substituted with cetyl moieties), termed CT-PEI. This compound is hydrophobic and has to be incorporated into liposomes in order to be suitable for gene transfer studies. Serum-induced plasmid DNA degradation assay demonstrated that CT-PEI-containing liposomal carriers could protect complexed DNA (probably via condensation). In vitro luciferase gene expression achieved using medium supplemented with 10% serum was comparable to that achieved in serum-reduced medium and was highest for CT-PEI/cholesterol liposomes, followed by CT-PEI/dioleoylphosphatidylcholine liposomes and PEI 600 Da (uncetylated) carrier. In vivo systemic transfer into mice was most efficient when liposome formulations contained CT-PEI and cholesterol. Higher luciferase expression was then observed in lungs than in liver. In conclusion: liposomes containing cetylated polyethylenimine and cholesterol are a suitable vehicle for investigating systemic plasmid DNA transfer into lungs.     

Gene Transfer to Lentil Protoplasts by Lipofection and Electroporation

Abstract

Cationic liposomes made of dipalmitoylphosphatidylcholine and stearylamine (9:1) were prepared by reverse-phase evaporation and were able to interact spontaneously with plasmid DNA. The loaded vesicles delivered a β-glucuronidase (GUS)-carrying plasmid to lentil Lens culinaris) protoplasts, leading to transient expression of the GUS reporter gene. The transfection efficiency achieved by using stearylamine-containing liposomes (lipofection) was comparable to the one obtained by electroporating the protoplasts at 500 μF and different field strengths. Furthermore, the combination of electroporation and lipofection, though reducing cell survival, increased the activity of the reporter enzyme detected in the cell lysates, yielding transient expression levels higher than those recorded after lipofection or electroporation alone.     

Protamine Sulfate Provides Enhanced and Reproducible Intravenous Gene Transfer by Cationic Liposome/DNA Complex

Abstract

A novel lipid/polycation/DNA (LPD) formulation has been developed for in vivo gene transfer. It involves the condensation of plasmid DNA with protamine sulfate, a cationic polypeptide, followed by the addition of DOTAP cationic liposomes. Compared with DOTAP/DNA complex, LPD offers greater protection of plasmid DNA against enzymatic digestion and gives consistently higher gene expression in mice via tail vein injection. The in vivo efficiency of LPD was dependent upon charge ratio and was also affected by the lipid used. Increasing the amount of DNA delivered induced an increase in gene expression. The optimal dose was approximately 50 μg per mouse, at which concentration approximately 10 ng luciferase protein per mg extracted tissue protein could be detected in the lung. Gene expression in the lung was detected as early as 1 h after injection, peaked at 6 h, and declined thereafter. Using LacZ as a reporter gene, it was shown that endothelial cells were the primary locus of transgene expression in both lung and spleen. No sign of inflammation in these organs was noticed. Since protamine sulfate has been proven to be non-toxic and only weakly immunogenic in humans, this novel vector may be useful for the clinical use of gene therapy.     

Polycation liposome-mediated gene transfer in vivo

The polycation liposome (PCL), a recently developed gene transfer system, is simply prepared by a modification of liposomes with cetylated polyethylenimine (PEI), and shows remarkable transgene efficiency with low cytotoxicity. In the present study, we investigated the applicability of PCLs for in vivo gene transfer, since the PCL-mediated transgene efficiency was found to be maintained in the presence of serum. PCLs composed of dioleoylphosphatidylethanolamine (DOPE) with 5 mol% cetyl PEI (PEI average mr. wt. 1800), were superior for transfection to those of dipalmitoylphosphatidylcholine (DPPC) and cholesterol (2:1 as molar ratio) with 5 mol% cetyl PEI in vitro, although the latter PCLs were more efficient for gene transfer in vivo. PCL-DNA complexes were injected into mice via a tail or the portal vein, with the DNA being a plasmid encoding green fluorescent protein (GFP) or luciferase; and the expression was monitored qualitatively or quantitatively, respectively. Tail vein injection resulted in high expression of both GFP and luciferase genes in lung, and portal vein injection resulted in high expression of both genes in the liver. Concerning the gene delivery efficiency, the PCL was found to be superior to PEI or cetyl PEI alone. The optimal conditions for in vivo transfection with PCLs were also examined.     

Polycation liposome-mediated gene transfer in vivo

The polycation liposome (PCL), a recently developed gene transfer system, is simply prepared by a modification of liposomes with cetylated polyethylenimine (PEI), and shows remarkable transgene efficiency with low cytotoxicity. In the present study, we investigated the applicability of PCLs for in vivo gene transfer, since the PCL-mediated transgene efficiency was found to be maintained in the presence of serum. PCLs composed of dioleoylphosphatidylethanolamine (DOPE) with 5 mol% cetyl PEI (PEI average mr. wt. 1800), were superior for transfection to those of dipalmitoylphosphatidylcholine (DPPC) and cholesterol (2:1 as molar ratio) with 5 mol% cetyl PEI in vitro, although the latter PCLs were more efficient for gene transfer in vivo. PCL-DNA complexes were injected into mice via a tail or the portal vein, with the DNA being a plasmid encoding green fluorescent protein (GFP) or luciferase; and the expression was monitored qualitatively or quantitatively, respectively. Tail vein injection resulted in high expression of both GFP and luciferase genes in lung, and portal vein injection resulted in high expression of both genes in the liver. Concerning the gene delivery efficiency, the PCL was found to be superior to PEI or cetyl PEI alone. The optimal conditions for in vivo transfection with PCLs were also examined.     

miR-483-3p靶向CD44抑制EGFR突变肺癌的作用研究

目的:探讨mi R-483-3p对CD44表达的调控作用及采用脂质体载药系统递送mi R-483-3p治疗表皮生长因子(epidermalgrowth factor receptor,EGFR)突变的非小细胞肺癌(non-small cell lung cancer,NSCLC)的作用。方法:通过mi R-483-3p靶基因的数据库发现CD44可能是mi R-483-3p的靶基因之一,从结构上及功能上进行验证。在EGFR酪氨酸激酶抑制剂(epidermal growth factor receptor-tyrosine kinase inhibitor, EGFR-TKI)耐药的NSCLC模型中,分别从基因及蛋白水平检测耐药模型及敏感模型中CD44的表达。在HCC827GR移植瘤模型中,采用脂质体-鱼精蛋白-DNA (liposome-polycation-DNA, LPD)载药系统递送mi R-483-3p进行治疗,观察肿瘤的生长情况。结果:双荧光素酶报告基因实验及Western blot实验结果显示CD44是mi R-483-3p的靶基因之一,且CD44在EGFR-TKI耐药模型中异常高表达(P0.05)。脂质体载药系统LPD-mi RNA-DSPE-PEG符合静脉给药要求,Size为66.93±21 nm,Zeta potential为8.7±2 m V,PDI (Polydispersity Index)为0.1,递送mi R-483-3p后能够抑制HCC827GR移植瘤的生长(P0.05)。结论:CD44为mi R-483-3p的靶基因之一,在耐药模型中高表达,脂质体载药系统给予mi R-483-3p能够抑制EGFR-TKI耐药肿瘤的生长。     

Biologically active, recombinant DNA in clathrin-coated vesicles isolated from rat livers after in vivo injection of liposome-encapsulated DNA

DNA entrapped in liposomes containing lactosylceramide in the bilayers is found to be associated with clathrin-coated vesicles isolated from the rat livers after intravenous injection of these liposomes. The presence of the exogenous DNA in the coated vesicles was detected by Southern blotting. The amount of DNA present in the coated vesicles does not appear to vary up to 4 h after injection of the liposomes into the animals. The recognition of the lactosyl group present in the liposome by the galactose receptor present on the surface of the different liver cells may lead to their internalization in a way analogous to receptor-mediated endocytosis of various macromolecules. DNA present in the lumen of the coated vesicles is found to be biologically active as evidenced by its replication in bacterial cells and mouse fibroblasts.     

Intrahepatic Distribution of Long-Circulating Liposomes Containing Polyethylene Glycol) Distearoyl Phosphatidylethanolamine

Abstract

We investigated the intrahepatic distribution in rats of liposomes of 85 or 130 nm diameter, which were sterically stabilized with a polyethylene glycol) derivative of phosphatidylethanolamine (PEG-PE) so as to increase their circulation time in blood. Various times after intravenous injection of radiolabeled ([³H-]cholesterylether) liposomes, parenchymal and non-parenchymal cells of the liver were isolated and their radioactivity content was determined. Control liposomes of 85 nm without PEG-PE distributed in an approximately 80:20 ratio to hepatocytes (H) and macrophages (M), respectively; the 130-nm control liposomes showed a 50:50 H/M distribution. Incorporation of PEG-PE reduced the rate of total liver uptake about 4-fold for liposomes of either size and shifted the H/M ratio to 60:40 for the smaller vesicles and to 40:60 for the larger ones. For both liposome sizes, PEG-PE apparently causes a shift in intrahepatic distribution in favor of the macrophages. It is concluded that PEG-PE has a stronger inhibitory effect on liposome uptake by hepatocytes than on uptake by macrophages. Attempts to shift liposome uptake more in favor of hepatocytes, by incorporation of lactosylceramide, failed. This compound, although causing an increase in hepatic uptake, particularly for the 130-nm liposomes, shifted the H/M ratio further towards the macrophages. We conclude that the galactose moiety of the glycolipid is sufficiently exposed on the surface of (PEG-PE)-containing liposomes to allow interaction with the galactose-binding lectin at the surface of the liver macrophage and that the extent of exposure is dependent on vesicle size.     

Therapeutic dendritic cell vaccine preparation using tumor RNA transfection: A promising approach for the treatment of prostate cancer

Background

Electroporation is an established technique for enhancing plasmid delivery to many tissues in vivo, including the skin. We have previously demonstrated efficient delivery of plasmid DNA to the skin utilizing a custom-built four-plate electrode. The experiments described here further evaluate cutaneous plasmid delivery using in vivo electroporation. Plasmid expression levels are compared to those after liposome mediated delivery.

Methods

Enhanced electrically-mediated delivery, and less extensively, liposome complexed delivery, of a plasmid encoding the reporter luciferase was tested in rodent skin. Expression kinetics and tissue damage were explored as well as testing in a second rodent model.

Results

Experiments confirm that electroporation alone is more effective in enhancing reporter gene expression than plasmid injection alone, plasmid conjugation with liposomes followed by injection, or than the combination of liposomes and electroporation. However, with two time courses of multiple electrically-mediated plasmid deliveries, neither the levels nor duration of transgene expression are significantly increased. Tissue damage may increase following a second treatment, no further damage is observed after a third treatment. When electroporation conditions utilized in a mouse model are tested in thicker rat skin, only higher field strengths or longer pulses were as effective in plasmid delivery.

Conclusion

Electroporation enhances reporter plasmid delivery to the skin to a greater extent than the liposome conjugation method tested. Multiple deliveries do not necessarily result in higher or longer term expression. In addition, some impact on tissue integrity with respect to surface damage is observed. Pulsing conditions should be optimized for the model and for the expression profile desired.     

A new cationic liposome for efficient gene delivery with serum into cultured human cells: a quantitative analysis using two independent fluorescent probes

Cationic liposomes are useful to transfer genes into eukaryotic cells in vitro and in vivo. However, liposomes with good transfection efficiency are often cytotoxic, and also require serum-free conditions for optimal activity. In this report, we describe a new formulation of cationic liposome containing DC-6-14, O,O'-ditetradecanoyl-N-(alpha-trimethylammonioacetyl)diethan olamine chloride, dioleoylphosphatidylethanolamine and cholesterol for gene delivery into cultured human cells. This liposome, dispersed in 5% serum-containing growth medium, efficiently delivered a plasmid DNA for GFP (green fluorescent protein) into more than 80% of the cultured human cell hybrids derived from HeLa cells and normal fibroblasts. Flow cytometric analysis revealed that the efficiency of the GFP gene expression was 40-50% in a tumor-suppressed cell hybrid, while it was greatly reduced in the tumorigenic counterpart. The enhanced GFP expression in tumor-suppressed cell hybrids was quantitatively well correlated with a prolonged presence of the plasmid DNA, which had been labeled with another fluorescent probe, ethidium monoazide, within the cells. These results suggest that a newly developed cationic liposome is useful for gene delivery in serum-containing medium into human cells and the stability of the plasmid DNA inside the cell is a crucial step in this liposome-mediated gene expression. The mechanisms by which cationic liposome mediates gene transfer into eukaryotic cells are also discussed.     

Liposome Distribution Under the Conditions of Transplantation Immunity Activation

Abstract

The distribution of small neutral liposomes from phosphatidylcholine (PC) and cholesterol (Choi), 7:5 molar ratio, when transplanting skin and renal grafts administered locally, intavenously (IV), and subcutaneously (SC) to determine the regularities of their delivery to the pathological nidus and their accumulation in the liver has been studied. It is stated that the liposome uptake by the skin allograft after SC injection is different from the one by the skin autograft in its more prolonged growth of radioactivity. The local injection of liposomes after renal transplantation also results in prolonged liposome uptake by the graft and regional lymph nodes. Liposomes uptake by the allograft after IV injection is found to take place during the first day both for skin and renal transplantation. It is evident that SC and local injections are the varieties of the lymphogenic way of liposome administration. When using liposomes containing immunosuppressants and antiischemic drugs lymphgeneous and IV administrations when combined can be effective.     

Targeted Delivery of Drugs and DNA with Liposomes

Abstract

This presentation is divided into three parts: long-circulating liposomes, immunoliposomes and gene transfer with liposomes. The mechanism of action for the poly(ethylene glycol)-phospholipid conjugates to prolong the circulation time of liposomes can be understood on the basis of steric barrier activity imposed by the flexible PEG chains on the liposome surface. The action of ganglioside GM₁, on the other hand, probably involves specific interactions with serum protein(s). Immunoliposomes can efficiently bind with the target only if the target is readily accessible and the liposomes stay in the circulation for a relatively long period of time. Coating the liposome surface with PEG chains or GM₁ enhances the target binding of immunoliposomes, except when PEG of greater than 5000 dalton is used. In this case, immunoliposome binding to the target is sterically hindered by the long PEG chains. To overcome the problem, antibody molecule is conjugated to the distal end of the PEG chain. This approach works well except that the liver uptake of immunoliposomes is somewhat enhanced. For the delivery of DNA into cells, a novel cationic amphiphile (DC-chol) is synthesized and is now used in clinical trials of gene therapy for melanoma. Current effort is concentrated on the means to enhance the level and duration of transgene expression.