Tissue-dependent factors affect gene delivery to tumors in vivo.

Systemic application of surface-shielded transferrin-polyethylenimine/DNA complexes leads to predominant DNA uptake and gene expression in Neuro2a tumors in syngeneic A/J mice. Similarly, high expression levels were found in Huh-7 and HepG2 human tumor xenografts in SCID mice after systemic application of surface-shielded EGF-PEG-PEI/DNA complexes. Significant DNA uptake but low gene expression were found in the M-3 melanoma while no DNA uptake and no gene expression were found in KB, 518A2, A549, and SW480 xenograft tumor models. To elucidate the reasons for these differences, the tumors were analyzed for vascularization and infiltration of macrophages. Neuro2a, Huh-7, and HepG2 tumors are well vascularized, with a high density of partially immature blood vessels and low numbers of infiltrating macrophages. The M-3 melanoma is well vascularized correlating with significant DNA uptake, however, necrosis and intensive infiltration by macrophages lead to rapid degradation of DNA. In contrast, the KB, 518A2, A549, and SW480 tumors are poorly vascularized, correlating with undetectable DNA uptake and gene expression. Using two different vector systems the data indicate that gene delivery to tumors in vivo is affected by tissue-dependent factors. Uptake of DNA into the tumor depends on vascularization of the tumor, while necrosis and macrophage infiltration may facilitate degradation of the DNA.

Nonviral gene transfer into fetal mouse livers (a comparison between the cationic polymer PEI and naked DNA).

We investigated the efficacy and safety of the cationic polymer polyethylenimine (PEI) as a potential tool for intrauterine gene delivery into livers of fetal mice in the last trimester of pregnancy (E17.5). Using luciferase as a reporter gene, transferrin-conjugated and ligand-free PEI/DNA complexes (containing 3 microg DNA) with varying PEI-nitrogen/DNA-phosphate (N/P) ratios and different PEI forms, branched (800, 25 kDa) and linear (22 kDa), were compared with naked DNA. Transgene expression was measured 48 h after administration of PEI/DNA complexes or naked DNA. Highest luciferase activity (9.8 x 10(3) relative light units (RLU)/mg of tissue protein) was observed with ligand-free PEI22/DNA mixtures at N/P 6.0. In addition, this formulation was associated with very low toxicity as compared to the other PEI/DNA-injected groups. Using beta-galactosidase as a reporter gene, transfection of single, but also small, clusters of cells was demonstrated throughout the liver. Injection of 3 microg naked DNA resulted in an 11-fold lower transgene expression value (0.9 x 10(3) RLU/mg of tissue protein) as compared to PEI22/DNA complexes. However, the administration of higher concentrated naked DNA (9 microg) into fetal livers yielded expression levels of 3.2 x 10(4) RLU/mg of tissue protein, a more than three-fold increase compared to PEI22/DNA complexes. Furthermore, the gene transfer efficacy of concentrated naked DNA was approximately 40 times higher in fetuses than in adults (0.8 x 10(3) RLU/mg of tissue protein), indicating that fetal tissue is especially amenable to the uptake and expression of naked DNA.

Tumor-targeted gene delivery: an attractive strategy to use highly active effector molecules in cancer treatment.

We have developed surface-shielded ligand-polycation based gene delivery systems which are able to target gene expression to distant tumors after systemic application. Tumor-specific targeting is achieved by (1) incorporation of cell-binding ligands; and (2) shielding of the complexes from non-specific interactions with blood components and non-target cells. Shielding of polycation/DNA complexes can be achieved by coating with either polyethylene glycol or by incorporating the ligand transferrin at high densities. Following systemic application, surface-shielded DNA complexes coding for a highly active, yet highly toxic cytokine, tumor necrosis factor-alpha (TNFalpha), localized gene expression to distant tumors, resulting in hemorrhagic tumor necrosis and inhibition of tumor growth. TNFalpha activity was confined to the tumor without systemic TNF-related toxicity. These results indicate that targeted gene delivery may be an attractive strategy to use highly potent molecules in cancer treatment.

Design and gene delivery activity of modified polyethylenimines.

The polycation polyethylenimine (PEI) has recently been widely employed for the design of DNA delivery vehicles. Gene delivery using PEI involves condensation of DNA into compact particles, uptake into the cells, release from the endosomal compartment into the cytoplasm, and uptake of the DNA into the nucleus. Particularly for in vivo gene delivery, optimal coordination and timing between DNA complexation for protection of the DNA from nucleases and the disassembly of the complexes is essential. For in vivo application, DNA complexes have to pass a variety of anatomical and physiological barriers, and an environment of biological fluids and extracellular matrix before reaching their targets. Furthermore, targeted gene delivery is seriously hampered by non-specific interactions with non-target cells. Strategies have been developed to protect transfection complexes from non-specific interactions and to increase target specificity and gene expression.

Different behavior of branched and linear polyethylenimine for gene delivery in vitro and in vivo.

BACKGROUND: Efficient gene transfer is a major challenge for non-viral gene therapy. Understanding how non-viral vectors initiate gene expression could lead to the development of new future vectors with enhanced efficacy. METHODS: Linear or branched polyethylenimine (PEI)/DNA complexes were generated in varying salt conditions and their transfection efficiencies were compared in vitro and in vivo using reporter genes, luciferase and green fluorescent protein, and rhodamine labeled DNA (pGeneGrip). RESULTS: The transfection efficiency of linear PEI22/DNA in vitro was generally greater than that of branched PEI/DNA when complexes were generated in salt containing buffer. However, PEI complexes generated under salt-free conditions generally had low transfection activity in vitro. In contrast, PEI22/DNA salt-free complexes were highly active in vivo. Branched PEI/DNA and salt containing PEI22/DNA complexes were generally 10-100-fold less active than the salt-free PEI22/DNA complexes. Salt-free PEI22/DNA complexes were small, but subsequently grew into aggregates when salt was added. In contrast, PEI25/DNA complexes remained small even after salt was added under the same conditions. Furthermore, PEI22/pGeneGrips complexes formed large aggregates associated with the cell membrane, cytoplasm and nucleus, while branched PEI complexes remained as small distinct particles associated with the cell membrane or in the cytoplasm. CONCLUSIONS: Branched and linear PEI/DNA complexes differ in their ability to transfect cells. The greater efficiency of linear PEI might be due to an inherent kinetic instability under salt conditions. Understanding how to employ this kinetic instability of linear PEI could help in designing future vectors with greater flexibility and transfection efficiency in vivo.

Tumor targeting with surface-shielded ligand--polycation DNA complexes.

Incorporation of the receptor binding ligands transferrin (Tf) or epidermal growth factor (EGF) into DNA/polyethylenimine (PEI) complexes was found to enhance gene transfer into tumor cell lines in a receptor-dependent manner. In systemic applications, the surface charge of DNA complexes dominated the in vivo characteristics of gene transfer. Administration of surface-shielded Tf-polycation/DNA complexes into the tail vein of A/J mice resulted in preferential gene delivery into distantly growing subcutaneous Neuro2a tumors. In contrast, application of positively charged DNA/PEI complexes directed gene transfer primarily to the lung. Two alternatives of masking the surface charge of complexes were accomplished. In the first case, shielding was obtained by covalently coating of DNA/Tf-PEI complexes with polyethylene glycol (PEG). Alternatively, incorporation of sufficient Tf protein into the DNA complexes resulted in charge shielding even without PEGylation. In the latter case lower-molecular weight polycations (25 kDa PEI for Tf-PEI complexes, or 32 kDa polylysine for AVET complexes) were used.

Polyethylenimine/DNA complexes shielded by transferrin target gene expression to tumors after systemic application.

Systemic application of positively charged polycation/DNA complexes has been shown to result in predominant gene expression in the lungs. Targeting gene expression to other sites, eg distant tumors, is hampered by nonspecific interactions largely due to the positive surface charge of transfection complexes. In the present study we show that the positive surface charge of PEI (25 kDa branched or 22 kDa linear)/DNA complexes can be efficiently shielded by covalently incorporating transferrin at sufficiently high densities in the complex, resulting in a dramatic decrease in nonspecific interactions, eg with erythrocytes, and decreased gene expression in the lung. Systemic application of transferrin-shielded PEI/DNA complexes into A/J mice bearing subcutaneously growing Neuro2a tumors via the tail vein resulted in preferential (100- to 500-fold higher) luciferase reporter gene expression in distant tumors as compared with the major organs including the lungs. Tumor targeting is also demonstrated by DNA uptake and beta-galactosidase gene expression in tumor cells. Assessing DNA distribution following systemic application significant amounts of DNA were found in the liver and tumor. However, in the liver, DNA was mainly taken up by Kupffer cells and degraded without significant transgene expression. In the tumor, DNA was associated mainly with tumor cells and frequently found near structures which resemble primitive blood vessels.

In vivo myocardial gene transfer: optimization, evaluation and direct comparison of gene transfer vectors.

The purpose was to determine the relative efficiency, toxicity and duration of expression following gene delivery by intramyocardial injection of naked DNA, naked DNA complexed to cationic liposomes, naked DNA complexed to cationic liposomes with integrin-targetting peptide, recombinant (E1-/E3-) adenovirus, recombinant adeno-associated virus and recombinant (ICP27-) herpes simplex virus. All vectors incorporated a LacZ reporter driven by a promoter containing the hCMV-IE promoter/enhancer. Efficiency was scored by counting positive cells in five standard microscopic sections harvested from the left ventricular apex. Rabbit hearts (n = 100) were examined from 2 to 56 days after injection. Uncomplexed and complexed naked DNA were very inefficient with less than one positive cell visible per heart. The viral vectors all resulted in robust gene expression with adenovirus being the most efficient by at least one order of magnitude before 21 days. However, despite disparate titres, the efficiency beyond 21 days of adenovirus and adeno-associated virus were comparable. In contrast to adeno-associated virus, both adenovirus and herpes-simplex virus were associated with a marked inflammatory response. Despite reporter gene activity appearing only after 21 days, adeno-associated virus shows comparative promise as a myocardial gene delivery vector.

In vivo myocardial gene transfer: optimization and evaluation of intracoronary gene delivery in vivo.

Clinical reports suggest that intracoronary delivery of adenoviruses encoding angiogenic growth factors, or their transactivators, has a therapeutic benefit. However there has not been a systematic assessment of the transfection efficiency of this technique in vivo. In rabbits we investigated the efficiency of myocardial gene transfer following intracoronary infusion of 1 x 10(-10) -1 x 10(12) p.f.u. of adenovirus in combination with interventions to enhance transfection. In five standard short axis sections, we were barely able to detect reporter gene expression following unmodified intracoronary infusion. Efficiency was not enhanced by the exclusion of blood and the increase of intracoronary dwell time through occlusive engagement of the left coronary ostium enabled by oxygenated perfluorocarbon emulsion as viral diluent. Of the interventions and pretreatments designed to increase vascular permeability, VEGF, calcium-free viral diluent and adenosine, only the latter tended to increase efficiency. However an intervention designed to increase the myocardial transcapillary gradient, by increasing venular pressure with pulmonary artery occlusion and arteriolar pressure with occlusion of the aorta above the coronary ostia, increased transfection efficiency by two orders of magnitude. Unfortunately the clinical utility of this technique may be limited by accompanying cardiac dilation and marked elevations in intracardiac pressure.

Development of transferrin-polycation/DNA based vectors for gene delivery to melanoma cells.

We describe the comparison of non-viral polycation transfection reagents, adenovirus-enhanced transferrinfection (AVET), polyethylenimine (PEI800) and transferrin-conjugated PEI800 (Tf-PEI800) in their ability to transfect murine and primary human melanoma cell lines. Expression of a reporter gene, cell surface marker and secreted protein (interleukin-2) was assessed for each vector system. Testing for luciferase reporter gene expression in murine and primary human cell lines, AVET and Tf-PEI800, both showed high levels of expression and comparable activity. Furthermore, when the melanoma cell line B16F10 was transfected with a cell surface marker up to approximately 97% of the cells expressed the protein on the cell surface. Assessing the levels of secreted IL-2 in murine cell lines, AVET/IL-2, Tf-PEI800/IL-2 and PEI800/IL-2 all expressed high levels of the cytokine (up to 20 microg IL-2/10(6) cells/24 h). In primary human melanoma cell lines, AVET/IL-2 transfected cells secreted more IL-2 than cells transfected with either Tf-PEI800/IL-2 or PEI800/IL-2. In murine melanoma cell culture experiments, positively charged PEI800/DNA and Tf-PEI800/DNA complexes gave similar transfection efficiencies. However, when subcutaneous tumors in mice were injected with the luciferase reporter gene complexed with either Tf-PEI800 or AVET, higher transfection activity was measured in the tumors as compared to ligand free PEI800/DNA complexes.

The expression of constitutively active isotypes of protein kinase C to investigate preconditioning.

The role of protein kinase C (PKC) in ischemic preconditioning remains controversial because of difficulties with both its measurement and pharmacological manipulation. We investigated preconditioning in isolated neonatal rat cardiocytes by expressing constitutively active isotypes of PKC. Observations at differing durations of simulated ischemia suggested beta-galactosidase (beta-gal) activity reflected viability within transfected myocytes. Preconditioning with 90 min of ischemia significantly increased beta-gal activity and myocyte survival after 6 h of ischemia; an effect abolished by PKC inhibitors. After co-transfection with plasmids encoding beta-gal and either constitutively active mutants of PKC-delta, PKC-alpha, wild type PKC-delta, or empty vector, cardiocytes were subjected to 6 h of ischemia. Only PKC-delta, rendered constitutively active by a limited deletion within the pseudosubstrate domain, consistently increased resistance to simulated ischemia (beta-gal activity was 85.6 +/- 11.9% versus 53.7 +/- 6.5% (p

beta-Galactosidase staining following intracoronary infusion of cationic liposomes in the in vivo rabbit heart is produced by microinfarction rather than effective gene transfer: a cautionary tale.

The myocardium is a potential target for the expression of exogenous genes to treat inherited and acquired diseases. Although adenovirus-mediated gene transfer has resulted in high-level gene transfer in vivo via direct intramyocardial injection and via a percutaneous intra-arterial route, the time-course of gene expression is limited by host immune responses. It was the aim of this study to test whether cationic liposome-mediated gene transfer, which does not suffer from the aforementioned problems, was feasible in the adult rabbit myocardium via a percutaneous transluminal approach. Doses of plasmid DNA encoding lacZ from 200-800 micrograms complexed to cationic liposomes resulted in X-gal conversion at day 3 with associated myocardial damage. We hypothesised that the damage was associated with macro-aggregates of cationic liposomes-DNA occluding the microcirculation. When such aggregates were excluded no X-gal conversion was seen in vivo. In order to show that X-gal conversion occurs in areas of infarction in the myocardium we caused closed chest infarction by deploying a platinum micro-embolisation coil in the circumflex coronary artery. At day 3 X-gal conversion was observed in the territory supplied by the occluded artery. Thus, microinfarction causes the false positive appearance of gene transfer when using a lacZ reporter gene.

Multiple deficit theory of schizophrenia: incidence of markers vs. symptoms.

Forty schizophrenic, 20 affective-disordered, and 40 matched normal control subjects were compared on postulated marker and symptom measures of schizophrenic deficits in: (a) affect; (b) attention; (c) proprioception; and (d) thought. The schizophrenic group was significantly more impaired on all four vulnerability markers than were the other two groups, while the schizophrenic and affective-psychotic groups showed comparable impairments on three of the psychotic symptom deficits. The incidence of multiple marker deficits was significantly greater in the schizophrenic than in the affective group. The hypothesis of independence of marker deficits was supported by the absence of any significant correlations among markers in the schizophrenic sample. The data support the theory that independent markers of schizophrenic vulnerability may potentiate schizophrenic disorders when their incidence is concurrent and at deficit levels.

Difference in reaction time between subjects with schizotypal and borderline personality disorders.

Patients with schizophrenic spectrum disorders and affective disorders were compared on a reaction time procedure. The nonhospitalized schizotypal subjects performed similarly to the schizophrenic patients on the crossover measure. Mean reaction time discriminated between hospitalized and nonhospitalized patients rather than between types of pathology.

Comparative effects of sulfur dioxide exposures at 5 degrees C and 22 degrees C in exercising asthmatics.

Either airway cooling or sulfur dioxide (SO2) can induce bronchoconstriction in many asthmatics. Whether these two stresses act synergistically is a question with important public health implications. Eight young adult asthmatic volunteers were exposed to SO2 at 0.0, 0.2, 0.4, and 0.6 ppm, during 5 min heavy exercise at 5 degrees C, both with high (approximately 85%) and with low (approximately 50%) relative humidity. Physiologic response increased with increasing SO2 concentration but did not vary significantly with humidity. Symptom response was marginally greater at low than at high humidity. Twenty-four asthmatics were exposed similarly to clean air and to 0.6 ppm SO2, at 5 degrees C and also at 22 degrees C, always at high relative humidity. For this group, physiologic and clinical responses to SO2 (in excess of responses to clean air) were highly significant, regardless of temperature. The mean excess responses at 5 degrees compared with those at 22 degrees C were not statistically significant in clean air or SO2. Thus, moderate cold stress exacerbated the untoward response to SO2 only slightly and inconsistently in these asthmatic subjects.

Laboratory evaluation of a disposable half-face mask for protection against ozone.

The ability of disposable half-face masks containing activated carbon to protect against inhaled ozone (O2) (nominal experimental exposure concentration, 0.5 ppm) was tested using a specially designed mechanical device simulating the breathing of a moderately exercising human, and then tested further by 18 volunteers exposed to O2 in a controlled-environment chamber for 2 h with intermittent mild exercise. As a control experiment, masks containing no activated carbon were tested similarly. On the mechanical device, carbon-impregnated masks removed 96 to 98% of ambient O3, whereas masks with no carbon removed 32 to 37%. Volunteers experienced typical respiratory irritation and temporary loss of forced expiratory function during O3 exposures when they wore the masks without carbon. These untoward effects were substantially reduced when masks containing carbon were worn. Volunteers tolerated the half-masks reasonably well, although some complained of discomfort. Disposable masks may be of significant benefit in protecting sensitive people from O2 exposures that they cannot readily avoid by other means.