Genetic pharmacology: progresses in siRNA delivery and therapeutic applications.

In the RNA interference process, the catalytic degradation of an endogenous mRNA results from the Watson-Crick complementary recognition by either a small silencing synthetic double-stranded ribonucleotide (siRNA) or by a small hairpin RNA (shRNA) produced in the cell by transcription from a DNA template. This interference process ideally results in an exquisitely specific mRNA suppression. The present review is dedicated to siRNAs. It describes the mechanism of RNA silencing and the main siRNA delivery techniques, with a focus on siRNA self-complexing to cationic lipids to form nanoparticles, which are called lipoplexes. The addition to lipoplexes of an anionic polymer leads to the ternary formulation APIRL (Anionic-Polymer-Interfering-RNA-Lipoplexes) with increased in vivo stability and biological efficacy. In terms of clinical development, the review focuses on therapeutic applications by intravenous delivery to the liver and inflammatory joints, and to localized siRNA delivery to the ocular sphere.

NF-kB related transgene expression in mouse tibial cranial muscle after pDNA injection followed or not by electrotransfer.

BACKGROUND: When activated, NF-κB can promote the nuclear import and transcription of DNA possessing NF-κB consensus sequences. Here, we investigated whether NF-κB is involved in the plasmid electrotransfer process. METHODS: Mouse tibial cranial muscles were transfected with plasmids encoding luciferase bearing or not NF-κB consensus sequences. Luciferase transgene expression was evaluated noninvasively by luminescence imaging and the number of pDNA copies in the same muscles by qPCR. RT-PCR of heat shock protein HsP70 mRNA evidenced cell stress. Western blots of phosphorylated IkBα were studied as a marker of NF-κB activation. RESULTS: Intra-muscular injection of a plasmid bearing a weak TATA-like promoter results in a very low muscle transfection level. Electrotransfer significantly increased both the number of pDNA copy and the transgene expression of this plasmid per DNA copy. Insertion of NF-κB consensus sequences into pDNA significantly increased the level of gene expression both with and without electrotransfer. Electrotransfer-induced cellular stress was evidenced by increased HsP70 mRNA. Phosphorylated IκBα was slightly increased by simple pDNA injection and a little more by electrotransfer. We also observed a basal level of phosphorylated IκBα and thus of free NF-κB in the absence of any stimulation. GENERAL SIGNIFICANCE: pDNA electrotransfer can increase transgene expression independently of NF-κB. The insertion of NF-κB consensus sequences into pDNA bearing a weak TATA-like promoter leads to enhanced transgene expression in muscle with or without gene electrotransfer. Finally, our results suggest that the basal amount of free NF-κB in muscle might be sufficient to enhance the activity of pDNA bearing NF-κB consensus sequences.

High and prolonged sulfamidase secretion by the liver of MPS-IIIA mice following hydrodynamic tail vein delivery of antibiotic-free pFAR4 plasmid vector.

Mucopolysaccharidosis type IIIA (MPS-IIIA) or Sanfilippo A syndrome is a lysosomal storage genetic disease that results from the deficiency of the N-sulfoglucosamine sulfohydrolase (SGSH) protein, a sulfamidase required for the degradation of heparan sulfate glycosaminoglycans (GAGs). The accumulation of these macromolecules leads to somatic organ pathologies, severe neurodegeneration and death. To assess a novel gene therapy approach based on prolonged secretion of the missing enzyme by the liver, mediated by hydrodynamic gene delivery, we first compared a kanamycin and an antibiotic-free expression plasmid vector, called pFAR4. Thanks to the reduced vector size, pFAR4 derivatives containing either a ubiquitous or a liver-specific promoter mediated a higher reporter gene expression level than the control plasmid. Hydrodynamic delivery of SGSH-encoding pFAR4 into MPS-IIIA diseased mice led to high serum levels of sulfamidase protein that was efficiently taken up by neighboring organs, as shown by the correction of GAG accumulation. A similar reduction in GAG content was also observed in the brain, at early stages of the disease. Thus, this study contributes to the effort towards the development of novel biosafe non-viral gene vectors for therapeutic protein expression in the liver, and represents a first step towards an alternative gene therapy approach for the MPS-IIIA disease.

Size-switchable polymer-based nanomedicines in the advanced therapy of rheumatoid arthritis.

Chronic inflammatory diseases such as rheumatoid arthritis represent a substantial socio-economic impact and have a high prevalence in the modern world. Nano-sized polymer therapeutics have shown suitable characteristics for becoming the next generation of anti-inflammatory nanomedicines. Here, we present biocompatible and stimuli-sensitive N-(2-hydroxypropyl)methacrylamide based polymer conjugates with the anti-inflammatory drug dexamethasone (DEX), which has been tailored for prolonged blood circulation, enhanced inflammatory site accumulation, site-specific drug release and subsequent elimination of the carrier via urine excretion. The hydrodynamic size of novel polymer-DEX nanomedicine was adjusted to prolong its blood circulation whilst maintaining the renal excretability of the polymer carrier after drug release in inflamed tissue. The therapeutic efficacy of the studied polymer nanomedicines was evaluated in a model of dissipated chronic arthritis, i.e. collagen II-induced arthritis, in mice. The pH-sensitive drug attachment enabled enhanced blood circulation with minimal systemic drug release, as well as rapid drug activation in affected joints. Importantly, unlike free DEX, the polymer nanomedicines were able to diminish joint inflammation and arthritis-induced bone damage - even at a reduced dosing regimen - as evaluated by micro computed tomography (micro-CT).

Cytosolic phospholipase A2α gene silencing in the myeloid lineage alters development of Th1 responses and reduces disease severity in collagen-induced arthritis.

OBJECTIVE: Several lines of evidence implicate cytosolic phospholipase A(2)α (cPLA(2)α) as a critical enzyme in inflammatory disorders, including rheumatoid arthritis. Since cells from the myeloid compartment regulate local and systemic disease pathogenesis, the present study was undertaken to examine the effect of cPLA(2)α inhibition in experimental arthritis, using a delivery system tailored to target monocyte functions by RNA interference (RNAi). METHODS: Mice with collagen-induced arthritis (CIA) were injected intravenously with an anti-cPLA(2)α small interfering RNA (siRNA) sequence (siPLA2) formulated as lipoplexes with the RPR209120/DOPE cationic liposome and a carrier DNA. The clinical course of joint inflammation was assessed, and the immunologic balance was analyzed by measuring T helper cell frequencies and cytokine expression. Biodistribution studies of siRNA were also performed. RESULTS: Weekly systemic injection of siPLA2 lipoplexes significantly reduced the incidence and severity of CIA, in both preventive and curative settings, as compared with findings in control animals. Histologic scores for inflammation and cartilage damage were reduced. The clinical effect was associated with local inhibition of tumor necrosis factor α secretion and lower cPLA(2)α expression and activity. The siPLA2 lipoplexes enabled triggering of in vivo RNAi-mediated gene silencing of cPLA(2)α in CD11b+ cells recovered from the spleen. While the treatment had no effect on anti-type II collagen (anti-CII) antibodies, CII-specific T helper cells producing interferon-γ, but not interleukin-17, in draining lymph node cells were decreased. CONCLUSION: Our findings indicate that systemic RNAi-mediated cPLA(2)α gene silencing in CD11b+ cells is effective in the treatment of CIA, and Th1 suppression is one of the potential underlying mechanisms, whereas Th17 suppression is not.

Soluble TNF-α receptor secretion from healthy or dystrophic mice after AAV6-mediated muscle gene transfer.

Muscle is an attractive target because it is easily accessible; it also offers a permissive environment for adeno-associated virus (AAV)-mediated gene transfer and has an abundant blood vascular supply providing an efficient transport system for the secretion of proteins. However, gene therapy of dystrophic muscle may be more difficult than that of healthy tissue because of degenerative-regenerative processes, and also because of the inflammatory context. In this study we followed the expression levels of secreted inhibitors of the proinflammatory tumor necrosis factor (TNF) cytokine after intramuscular (i.m.) injection of AAV6 into dystrophic mdx and healthy C57BL/10 mice. We used two chimeric proteins, namely, the human or murine TNF-soluble receptor I fused with the murine heavy immunoglobulin chain. We conducted an AAV6 dose-response study and determined the kinetics of transgene expression. In addition, we followed the antibody response against the transgenes and studied their expression pattern in the muscle. Our results show that transduction efficiency is reduced in dystrophic muscles as compared with healthy ones. Furthermore, we found that the immune response against the secreted protein is stronger in mdx mice. Together, our results underscore that the pathological state of the muscle has to be taken into consideration when designing gene therapy approaches.

Generation of high-titer neutralizing antibodies against botulinum toxins A, B, and E by DNA electrotransfer.

Botulinum neurotoxins are known to be among the most toxic known substances. They produce severe paralysis by preventing the release of acetylcholine at the neuromuscular junction. Thus, new strategies for efficient production of safe and effective anti-botulinum neurotoxin antisera have been a high priority. Here we describe the use of DNA electrotransfer into the skeletal muscle to enhance antiserum titers against botulinum toxin serotypes A, B, and E in mice. We treated animals with codon-optimized plasmid DNA encoding the nontoxic but highly immunogenic C-terminal heavy chain fragment of the toxin. By employing both codon optimization and the electrotransfer procedure, the immune response and corresponding neutralizing antiserum titers were markedly increased. The cellular localization of the antigen and the immunization regimens were also shown to increase neutralizing titers to >100 IU/ml. This study demonstrates that DNA electrotransfer is an effective procedure for raising neutralizing antiserum titers to remarkably high levels.

Widespread biochemical correction of murine mucopolysaccharidosis type VII pathology by liver hydrodynamic plasmid delivery.

Mucopolysaccharidosis type VII (MPS VII) is a lysosomal storage disease caused by a deficiency of the acid hydrolase beta-glucuronidase. MPS VII mice develop progressive lysosomal accumulation of glycosaminoglycans (GAGs) within multiple organs, including the brain. Using this animal model, we compared two plasmid gene administration techniques: muscle electrotransfer and liver-directed transfer using hydrodynamic injection. We have evaluated both the expression kinetics and the biodistribution of beta-glucuronidase activity after gene transfer, as well as the correction of biochemical abnormalities in various organs. This study shows that MPS VII mice treated with a plasmid-bearing mouse beta-glucuronidase cDNA, acquire the ability to produce the beta-glucuronidase enzyme for an extended period of time. The liver seemed to be more appropriate than the muscle as a target organ to enable enzyme secretion into the systemic circulation. A beneficial effect on the MPS VII pathology was also observed, as liver-directed gene transfer led to the correction of secondary enzymatic elevations and to the reduction of GAGs storage in peripheral tissues and brain, as well as to histological correction in many tissues. This work is one of the first examples showing that non-viral plasmid DNA delivery can lead to improvements in both peripheral and brain manifestations of MPS VII disease. It confirms the potential of non-viral systemic gene transfer strategy in neurological lysosomal disorders.

Real-time monitoring of cell transplantation in mouse dystrophic muscles by a secreted alkaline phosphatase reporter gene.

Transplantation of muscle precursor cells (MPCs) is a promising approach for the treatment of muscular dystrophies. However, preclinical and clinical results have shown that the technology is not yet efficient enough for most therapeutic applications. Among the problems that remain unsolved are low cellular survival, poor proliferation and lack of migration of the transplanted cells. One major technical hurdle for the optimization of transplantation protocols is how to follow precisely the fate of the cells after transplantation. In this study, we examined the use of a secreted form of the mouse alkaline phosphatase (mSeAP) enzyme as the reporter system transduced into MPCs using a retroviral vector. We show that circulating mSeAP could be detected in the serum of the transplanted mice at different time points after MPC transplantation. We also found that the level of circulating mSeAP is highly correlated with the number of transplanted cells and that mSeAP is an excellent histological marker. Further, studying the levels of circulating mSeAP compared with the number of muscle fibers positive to mSeAP and to dystrophin, enabled detailed analyses of bottleneck steps for successful transplantation. Taken together, our results show that mSeAP is an excellent quantitative 'real-time' reporter gene for cell therapy preclinical studies.

Effects of ciliary muscle plasmid electrotransfer of TNF-alpha soluble receptor variants in experimental uveitis.

Intraocular inflammation has been recognized as a major factor leading to blindness. Because tumor necrosis factor-alpha (TNF-alpha) enhances intraocular cytotoxic events, systemic anti-TNF therapies have been introduced in the treatment of severe intraocular inflammation, but frequent re-injections are needed and are associated with severe side effects. We have devised a local intraocular nonviral gene therapy to deliver effective and sustained anti-TNF therapy in inflamed eyes. In this study, we show that transfection of the ciliary muscle by plasmids encoding for three different variants of the p55 TNF-alpha soluble receptor, using electrotransfer, resulted in sustained intraocular secretion of the encoded proteins, without any detection in the serum. In the eye, even the shorter monomeric variant resulted in efficient neutralization of TNF-alpha in a rat experimental model of endotoxin-induced uveitis, as long as 3 months after transfection. A subsequent downregulation of interleukin (IL)-6 and iNOS and upregulation of IL-10 expression was observed together with a decreased rolling of inflammatory cells in anterior segment vessels and reduced infiltration within the ocular tissues. Our results indicate that using a nonviral gene therapy strategy, the local self-production of monomeric TNF-alpha soluble receptors induces a local immunomodulation enabling the control of intraocular inflammation.

Vascular endothelial growth factor reduced hypoxia-induced death of human myoblasts and improved their engraftment in mouse muscles.

Muscle precursor cell (myoblasts) transplantation is considered as a potential approach to restore dystrophin expression in Duchenne muscular dystrophy (DMD) patients. The study purpose was to verify the implication of hypoxia in the myoblast death observed after their transplantation and also to evaluate the potential beneficial effects of vascular endothelial growth factor (VEGF) overexpression on myoblast engraftment in a murine model. Pimonidazole hydrochloride (hypoxyprobe-1) was used to mark selectively myoblasts to evaluate their hypoxia in vivo. In vitro, hypoxia was induced by culturing human myoblasts in hypoxic environment. In vitro effects of VEGF(165) on survival of human cells was assessed by Hoescht-PI labeling. Tibialis anterior (TA) female mouse muscles were electroporated with a plasmid containing the VEGF(165) or with an empty vector. Circulating VEGF concentration was assessed by ELISA. After 2 weeks of electroporation, severe combined immunodeficient (SCID) mice were transplanted with 800 000 human male myoblasts labeled with radioactive thymidine. Mouse muscles were harvested 2 and 4 days later and myoblast survival and proliferation were evaluated by scintigraphy and Y chromosome quantitative PCR. The long-term graft success was evaluated using gamma-radiograph imaging and by counting the dystrophin positive muscle fibers. Hypoxyprobe labeling has shown that most of the transplanted myoblasts were hypoxic. The transplantation of radioactive male myoblasts in female mice electroporated with the VEGF(165) plasmid demonstrated that VEGF reduced their death by 10% but did not improve their proliferation. VEGF(165) enhanced human myoblast survival in vitro under hypoxic conditions. Electroporation of TA muscles of SCID mouse with the vector coding for VEGF(165) promoted angiogenesis and improved by 1.5-fold the success of myoblast transplantation in comparison with the control mice that were electroporated with the empty vector. These results indicate that hypoxia is partially responsible for the death of the transplanted myoblasts. VEGF can be used to improve myoblast survival and the graft success.

Current data on ATP-containing liposomes and potential prospects to enhance cellular energy status for hepatic applications.

The pharmacological use of adenosine triphosphate (ATP), although promising, is restricted due to poor cellular penetration and drastic hydrolysis that is markedly accelerated in vivo by ectoenzymes. In the literature, liposomes have proven efficient in offering a physical barrier to extracellular enzymes and favor penetration into cells. First, this review addresses the issues raised by ATP development in pharmaceutics. Second, studies conducted with ATP liposomally entrapped (lipo-ATP) are described, including pharmaco-technical formulation engineering and related models of assessment. Finally, potential directions for research to better target ATP penetration into the liver are considered. Lipo-ATP were formulated for a number of applications, including sepsis-related disorders; spermatozoid alteration; brain ischemia episodes; and ophthalmic, cardiac, and hepatic use. Key formulation parameters need to be carefully considered to optimize stability and entrapment yield value, and to define the manufacturing process. Positive lipids, such as stearylamine, increase entrapment yield value by electrostatic interaction with negatively charged ATP. A freezing-thawing step in the manufacturing process considerably increases entrapment yield value. Lipo-ATP were assessed using cell culture, isolated organs, and animal experimental models. Very promising results were obtained with antimyosin PEGylated immunoliposomes using isolated rat hearts and experimental myocardial infarction in rabbits. In hepatic applications, lipo-ATP are effective in preventing liver injury during shock and to improve the energy status of cold-stored rat liver, in particular, if liposomes are loaded with apolipoprotein E (ApoE). For liver delivery, liposome size needs to be lower than 100 nm to allow diffusion through the Disse space, but liposome flexibility and lipid content may also influence liver uptake. The role of the liposome charge remains unclear. ApoE and the ligand for the asialoglycoprotein receptor [ASGPr) were both used in the literature, but the ASGPr seems more promising. Ligand-ASGPr interaction is based on the sugar preference (N-acetylgalactosamine>>galactose), the antennary structure (tetra>tri>di>monoantennary), and sugar spacing. Numerous high-affinity ligands have been extracted or designed to target hepatocytes, which can be classified according to their origin (i.e., natural, hemisynthetic, or synthetic). Synthetic ASGPr, such as Gal-C4-Chol (cholesten-5-yloxy-N-(4-((1-imino-2-D-thiogalactosylethyl)formamide), are composed of a lipid anchor (e.g., cholesteryl), a spacer (C2 to C6 chain), and a sugar head (galactose or lactose). The formulation includes ligand incorporation, by either simple preincubation or covalent graft, onto preformulated liposomes or direct mixing with other lipids. The ligand-loaded liposomes encapsulated pharmacological agents, markers, or plasmid DNA. Interesting results were obtained with antitumor or antioxidant agents to promote drug penetration in cell culture (e.g., primary rat hepatocyte or HepG2) and specific targeting to hepatocyte in isolated perfused liver (pharmacokinetic studies). Effectiveness was demonstrated in experimental models (e.g., tumor-bearing animals and hepatotoxic models). These targeted formulations were less toxic than standard formulations and controls. A development scheme that can be applied to other drugs, which may benefit from improved hepatic targeting, is proposed to optimize liposome characteristics and ligand structure, including verifications such as the displacement-binding test, ligand incorporation, cell internalization, tissue diffusion, organ and receptor specificity, and efficiency in experimental models.

Anionic pH-sensitive pegylated lipoplexes to deliver DNA to tumors.

Anionic pegylated lipoplexes have been prepared from the combined formulation of cationic lipoplexes and pegylated anionic liposomes. To this end, two original (bis- and tetra-) carboxylated cholesterol derivatives have been synthesised. Titration of the particle surface charge was realised to determine the ratio between anionic and cationic lipids that would give pH-sensitive complexes. This ratio has been optimised to form particles sensitive to pH change in the range 5.5-6.5. Compaction of DNA into these newly formed anionic complexes was checked by DNA accessibility to picogreen and DNA electrophoresis on an agarose gel. Gene expression of the formulated gene was similar for the cationic formulation taken as a control and the anionic formulations prepared. The pH-sensitive properties of these formulations was shown in vitro using bafilomycin, a vacuolar H(+)ATPase inhibitor. The efficiency of the new formulations to deliver DNA to the tumor was compared with cholesteryl hemisuccinate (CHEMS) formulations. The tetracarboxylated compound gave the most efficient formulations for tumor delivery in vivo.

Assessment of the targeting specificity of a fluorescent albumin conceived as a preclinical agent of the liver function.

In the context of increasing liver diseases, no contrast agent is currently available in Europe and the United States to directly assess the liver function. Only neolactosylated human serum albumin is being clinically used in Asia. In order to perform preclinical studies in the context of liver diseases, we conceived a fluorescent lactosylated albumin for the quantification of liver functional cells (l-Cyal). Precise characterization was achieved in order to determine the amounts of lactose and Cyanine 5 (Cy5) coupled to the albumin. In addition, potential aggregation was characterized by asymmetrical flow field-flow fractionation hyphenated to multi-angle light scattering (AF4-MALS). The optimal functionalized albumin exhibited a mass greater than 87 kDa which corresponds to the addition of 34 lactose moieties per protein and 1-2 Cy5 labels. Also, no significant formation of aggregates could be identified due to the modification of the native albumin. In healthy mice, the accumulation of l-Cyal in the liver and its selectivity for hepatocyte cells were shown by optical imaging and flow cytometry. Administration of l-Cyal to mice bearing liver metastases showed a reduced signal in the liver related to a decrease in the number of hepatocytes. The l-Cyal bioimaging contrast agent could be particularly useful for assessing the state of liver related diseases.

Plasmid electrotransfer of eye ciliary muscle: principles and therapeutic efficacy using hTNF-alpha soluble receptor in uveitis.

Due to its small size and particular isolating barriers, the eye is an ideal target for local therapy. Recombinant protein ocular delivery requires invasive and painful repeated injections. Alternatively, a transfected tissue might be used as a local producer of transgene-encoded therapeutic protein. We have developed a nondamaging electrically mediated plasmid delivery technique (electrotransfer) targeted to the ciliary muscle, which is used as a reservoir tissue for the long-lasting expression and secretion of therapeutic proteins. High and long-lasting reporter gene expression was observed, which was restricted to the ciliary muscle. Chimeric TNF-alpha soluble receptor (hTNFR-Is) electrotransfer led to elevated protein secretion in aqueous humor and to drastic inhibition of clinical and histological inflammation scores in rats with endotoxin-induced uveitis. No hTNFR-Is was detected in the serum, demonstrating the local delivery of proteins using this method. Plasmid electrotransfer to the ciliary muscle, as performed in this study, did not induce any ocular pathology or structural damage. Local and sustained therapeutic protein production through ciliary muscle electrotransfer is a promising alternative to repeated intraocular protein administration for a large number of inflammatory, degenerative, or angiogenic diseases.

Phosphoramidate oligonucleotides as potent antisense molecules in cells and in vivo.

Antisense oligonucleotides are designed to specifically hybridize to a target messenger RNA (mRNA) and interfere with the synthesis of the encoded protein. Uniformly modified oligonucleotides containing N3'-P5' phosphoramidate linkages exhibit (NP) extremely high-affinity binding to single-stranded RNA, do not induce RNase H activity, and are resistant to cellular nucleases. In the present work, we demonstrate that phosphoramidate oligonucleotides are effective at inhibiting gene expression at the mRNA level, by binding to their complementary target present in the 5'-untranslated region. Their mechanism of action was demonstrated by comparative analysis of three expression systems that differ only by the composition of the oligonucleotide target sequence (HIV-1 polypurine tract or PPT sequence) present just upstream from the AUG codon of the firefly luciferase reporter gene: the experiments have been done on isolated cells using oligonucleotide delivery mediated by cationic molecules or streptolysin O (SLO), and in vivo by oligonucleotide electrotransfer to skeletal muscle. In our experimental system phosphoramidate oligonucleotides act as potent and specific antisense agents by steric blocking of translation initiation; they may prove useful to modulate RNA metabolism while maintaining RNA integrity.

Electrotransfer into skeletal muscle for protein expression.

An efficient and safe method to deliver DNA in vivo is a requirement for several purposes, such as study of gene function and gene therapy applications. Among the different non-viral delivery methods currently under investigation, in vivo DNA electrotransfer has proven to be one of the most efficient and simple. This technique is a physical method of gene delivery consisting in local application of electric pulses after DNA injection. Although this technique can be applied to almost any tissue of a living animal, including tumors, skin, liver, kidney, artery, retina, cornea or even brain, this review will focus on electrotransfer of plasmid DNA into skeletal muscle and its possible uses in gene therapy, vaccination, or functional studies. Skeletal muscle is a good target for electrotransfer of DNA as it is: a large volume easily accessible, an endocrine organ capable of expressing several local and systemic factors, and muscle fibres as post-mitotic cells have a long lifespan that allows long-term gene expression. In this review, we describe the mechanism of DNA electrotransfer, we assess toxicity and safety considerations related to this technique, and we focus on important therapeutic applications of electrotransfer demonstrated in animal models in recent years.

Optical imaging of luminescence for in vivo quantification of gene electrotransfer in mouse muscle and knee.

BACKGROUND: Optical imaging is an attractive non-invasive way to evaluate the expression of a transferred DNA, mainly thanks to its lower cost and ease of realization. In this study optical imaging was evaluated for monitoring and quantification of the mouse knee joint and tibial cranial muscle electrotransfer of a luciferase encoding plasmid. Optical imaging was applied to study the kinetics of luciferase expression in both tissues. RESULTS: The substrate of luciferase (luciferin) was injected either intraperitonealy (i.p.) or in situ into the muscle or the knee joint. Luminescence resulting from the luciferase-luciferin reaction was measured in vivo with a cooled CCD camera and/or in vitro on tissue lysate. Maximal luminescence of the knee joint and muscle after i.p. (2.5 mg) or local injection of luciferin (50 microg in the knee joint, 100 microg in the muscle) were highly correlated. With the local injection procedure adopted, in vivo and in vitro luminescences measured on the same muscles significantly correlated. Luminescence measurements were reproducible and the signal level was proportional to the amount of plasmid injected. In vivo luciferase activity in the electrotransfered knee joint was detected for two weeks. Intramuscular electrotransfer of 0.3 or 3 microg of plasmid led to stable luciferase expression for 62 days, whereas injecting 30 microg of plasmid resulted in a drop of luminescence three weeks after electrotransfer. These decreases were partially associated with the development of an immune response. CONCLUSION: A particular advantage of the i.p. injection of substrate is a widespread distribution at luciferase production sites. We have also highlighted advantages of local injection as a more sensitive detection method with reduced substrate consumption. Besides, this route of injection is relatively free of uncontrolled parameters, such as diffusion to the target organ, crossing of biological barriers and evidencing variations in local enzymatic kinetics, probably related to the reaction medium in the targeted organ. Optical imaging was shown to be a sensitive and relevant technique to quantify variations of luciferase activity in vivo. Further evaluation of the effective amount of luciferase in a given tissue by in vivo optical imaging relies on conditions of the enzymatic reaction and light absorption and presently requires in vitro calibration for each targeted organ.

Anti-inflammatory effects of PJ34, a poly(ADP-ribose) polymerase inhibitor, in transient focal cerebral ischemia in mice.

BACKGROUND AND PURPOSE: Activation of poly(ADP-ribose) polymerase (PARP) is deleterious during cerebral ischemia. We assessed the influence of PARP activation induced by cerebral ischemia on the synthesis of proinflammatory mediators including the cytokines, tumour necrosis factor-alpha (TNF-alpha) and interleukin-6 (IL-6) and the adhesion molecules, E-selectin and intercellular adhesion molecule-1 (ICAM-1). EXPERIMENTAL APPROACH: Ischemia was induced by intravascular occlusion of the left middle cerebral artery for 1 h in male Swiss mice anaesthetized with ketamine and xylazine. The PARP inhibitor PJ34 (1.25-25 mg kg(-1)) was administered intraperitoneally 15 min before and 4 hours after, the onset of ischemia. Animals were killed 6 h or 24 h after ischemia and cerebral tissue removed for analysis. KEY RESULTS: Ischemia increased TNF-alpha protein in cerebral tissue at 6 and 24 h after ischemia. All doses of PJ34 blocked the increase in TNF-alpha at 6 h and 25 mg kg(-1) PJ34 had a sustained effect for up to 24 h. Quantitative real time polymerase chain reaction showed that PJ34 (25 mg kg(-1)) reduced the increase in TNF-alpha mRNA by 70% at 6 h. PJ34 also prevented the increase in mRNAs encoding IL-6 (-41%), E-selectin (-81%) and ICAM-1 (-54%). PJ34 (25 mg kg(-1)) reduced the infarct volume (-26%) and improved neurological deficit, 24 h after ischemia. CONCLUSIONS AND IMPLICATIONS: PJ34 inhibited the increase in the mRNAs of four inflammatory mediators, caused by cerebral ischemia. The contribution of this effect of PJ34 to neuroprotection remains to be clarified.

Antiangiogenic effect of interleukin-10 in ischemia-induced angiogenesis in mice hindlimb.

Ischemia induces both hypoxia and inflammation that trigger angiogenesis. The inflammatory reaction is modulated by production of anti-inflammatory cytokines. This study examined the potential role of a major anti-inflammatory cytokine, interleukin (IL)-10, on angiogenesis in a model of surgically induced hindlimb ischemia. Ischemia was produced by artery femoral occlusion in both C57BL/6J IL-10(+/+) and IL-10(-/-) mice. After 28 days, angiogenesis was quantified by microangiography, capillary, and arteriole density measurement and laser Doppler perfusion imaging. The protein levels of IL-10 and vascular endothelial growth factor (VEGF) were determined by Western blot analysis in hindlimbs. IL-10 was markedly expressed in the ischemic hindlimb of IL-10(+/+) mice. Angiogenesis in the ischemic hindlimb was significantly increased in IL-10(-/-) compared with IL-10(+/+) mice. Indeed, angiographic data showed that vessel density in the ischemic leg was 10.2+/-0.1% and 5.7+/-0.4% in IL-10(-/-) and IL-10(+/+) mice, respectively (P:<0.01). This corresponded to improved ischemic/nonischemic leg perfusion ratio by 1.4-fold in IL-10(-/-) mice compared with IL-10(+/+) mice (0.87+/-0. 05 versus 0.63+/-0.01, respectively; P:<0.01). Revascularization was associated with a 1.8-fold increase in tissue VEGF protein level in IL-10(-/-) mice compared with IL-10(+/+) mice (P:<0.01). In vivo electrotransfer of murine IL-10 cDNA in IL-10(-/-) mice significantly inhibited both the angiogenic process and the rise in VEGF protein level observed in IL-10(-/-) mice. No changes in vessel density or VEGF content were observed in the nonischemic hindlimb. These findings underscore the antiangiogenic effect of IL-10 associated with the downregulation of VEGF expression and suggest a role for the inflammatory balance in the modulation of ischemia-induced angiogenesis.