Alternatives to in vivo tests to detect endocrine disrupting chemicals (EDCs) in fish and amphibians--screening for estrogen, androgen and thyroid hormone disruption.

Endocrine disruption is considered a highly relevant hazard for environmental risk assessment of chemicals, plant protection products, biocides and pharmaceuticals. Therefore, screening tests with a focus on interference with estrogen, androgen, and thyroid hormone pathways in fish and amphibians have been developed. However, they use a large number of animals and short-term alternatives to animal tests would be advantageous. Therefore, the status of alternative assays for endocrine disruption in fish and frogs was assessed by a detailed literature analysis. The aim was to (i) determine the strengths and limitations of alternative assays and (ii) present conclusions regarding chemical specificity, sensitivity, and correlation with in vivo data. Data from 1995 to present were collected related to the detection/testing of estrogen-, androgen-, and thyroid-active chemicals in the following test systems: cell lines, primary cells, fish/frog embryos, yeast and cell-free systems. The review shows that the majority of alternative assays measure effects directly mediated by receptor binding or resulting from interference with hormone synthesis. Other mechanisms were rarely analysed. A database was established and used for a quantitative and comparative analysis. For example, a high correlation was observed between cell-free ligand binding and cell-based reporter cell assays, between fish and frog estrogenic data and between fish embryo tests and in vivo reproductive effects. It was concluded that there is a need for a more systematic study of the predictive capacity of alternative tests and ways to reduce inter- and intra-assay variability.

Deleterious functional consequences of perfluoroalkyl substances accumulation into the myelin sheath.

Exposure to persistent organic pollutants during the perinatal period is of particular concern because of the potential increased risk of neurological disorders in adulthood. Here we questioned whether exposure to perfluorooctanoic acid (PFOA) and perfluorooctane sulfonate (PFOS) could alter myelin formation and regeneration. First, we show that PFOS, and to a lesser extent PFOA, accumulated into the myelin sheath of postnatal day 21 (p21) mice, whose mothers were exposed to either PFOA or PFOS (20 mg/L) via drinking water during late gestation and lactation, suggesting that accumulation of PFOS into the myelin could interfere with myelin formation and function. In fact, PFOS, but not PFOA, disrupted the generation of oligodendrocytes, the myelin-forming cells of the central nervous system, derived from neural stem cells localised in the subventricular zone of p21 exposed animals. Then, cerebellar slices were transiently demyelinated using lysophosphatidylcholine and remyelination was quantified in the presence of either PFOA or PFOS. Only PFOS impaired remyelination, a deleterious effect rescued by adding thyroid hormone (TH). Similarly to our observation in the mouse, we also showed that PFOS altered remyelination in Xenopus laevis using the Tg(Mbp:GFP-ntr) model of conditional demyelination and measuring, then, the number of oligodendrocytes. The functional consequences of PFOS-impaired remyelination were shown by its effects using a battery of behavioural tests. In sum, our data demonstrate that perinatal PFOS exposure disrupts oligodendrogenesis and myelin function through modulation of TH action. PFOS exposure may exacerbate genetic and environmental susceptibilities underlying myelin disorders, the most frequent being multiple sclerosis.

Adiponectin expression and metabolic markers in obesity and Type 2 diabetes.

BACKGROUND: Adiponectin has emerged over the last decade as a key adipokine linking obesity, insulin resistance, and Type 2 diabetes. However, the molecular mechanisms controlling adiponectin expression in adipose tissue are not fully elucidated. Furthermore, increasing evidence indicates that peroxisome proliferator-activated receptor- γ (PPAR-γ) plays an important, and beneficial, role in modulating adiponectin expression. AIM: The aim of the present study was to assess the separate role of obesity and Type 2 diabetes in the relationship between endogenous PPAR-γ signaling and adiponectin expression in subcutaneous adipose tissue. SUBJECTS AND METHODS: Enzyme-linked immuno sor bent assay and real time quantitative PCR analysis were carried out in overweight, obese, and/or diabetic Tunisian patients who underwent an abdominal surgery. RESULTS: These results collectively indicate that circulating levels of adiponectin were decreased in all overweight, obese, and/or diabetic (p<0.001). However, the subcutaneous mRNA expression of adiponectin was reduced only in diabetics (p<0.01) but presents some discrepancies in obese individuals. Moreover, mRNA levels of adiponectin were positively correlated with levels of mRNA encoding PPARγ and its heterodimeric partner retinoid X receptor-α (RXR-α), in both obese and diabetic patients. CONCLUSION: Our study on Tunisian patients shows impaired regulation of circulating and mRNA adiponectin levels dependent of metabolic disorders in obesity and Type 2 diabetes. The data suggest that subcutaneous adipose tissue may play an important role in modulating adiponectin expression in diabetes and obesity. Moreover, adiponectin mRNA could be potentially regulated by endogenous PPARγ/RXRα-dependent pathways.

Adult neural stem cell fate is determined by thyroid hormone activation of mitochondrial metabolism.

OBJECTIVE: In the adult brain, neural stem cells (NSCs) located in the subventricular zone (SVZ) produce both neuronal and glial cells. Thyroid hormones (THs) regulate adult NSC differentiation towards a neuronal phenotype, but also have major roles in mitochondrial metabolism. As NSC metabolism relies mainly on glycolysis, whereas mature cells preferentially use oxidative phosphorylation, we studied how THs and mitochondrial metabolism interact on NSC fate determination. METHODS: We used a mitochondrial membrane potential marker in vivo to analyze mitochondrial activity in the different cell types in the SVZ of euthyroid and hypothyroid mice. Using primary adult NSC cultures, we analyzed ROS production, SIRT1 expression, and phosphorylation of DRP1 (a mitochondrial fission mediator) as a function of TH availability. RESULTS: We observed significantly higher mitochondrial activity in cells adopting a neuronal phenotype in vivo in euthyroid mice. However, prolonged hypothyroidism reduced not only neuroblast numbers but also their mitochondrial activity. In vitro studies showed that TH availability favored a neuronal phenotype and that blocking mitochondrial respiration abrogated TH-induced neuronal fate determination. DRP1 phosphorylation was preferentially activated in cells within the neuronal lineage and was stimulated by TH availability. CONCLUSIONS: These results indicate that THs favor NSC fate choice towards a neuronal phenotype in the adult mouse SVZ through effects on mitochondrial metabolism.

Adult neural stem cell cycling in vivo requires thyroid hormone and its alpha receptor.

Thyroid hormones (TH) are essential for brain development. However, information on if and how this key endocrine factor affects adult neurogenesis is fragmentary. We thus investigated the effects of TH on proliferation and apoptosis of stem cells in the subventricular zone (SVZ), as well as on migration of transgene-tagged neuroblasts out of the stem cell niche. Hypothyroidism significantly reduced all three of these processes, inhibiting generation of new cells. To determine the mechanisms relaying TH action in the SVZ, we analyzed which receptor was implicated and whether the effects were played out directly at the level of the stem cell population. The alpha TH receptor (TRalpha), but not TRbeta, was found to be expressed in nestin positive progenitor cells of the SVZ. Further, use of TRalpha mutant mice showed TRalpha to be required to maintain full proliferative activity. Finally, a direct TH transcriptional effect, not mediated through other cell populations, was revealed by targeted gene transfer to stem cells in vivo. Indeed, TH directly modulated transcription from the c-myc promoter reporter construct containing a functional TH response element containing TRE but not from a mutated TRE sequence. We conclude that liganded-TRalpha is critical for neurogenesis in the adult mammalian brain.

Differential thyroid hormone sensitivity of fast cycling progenitors in the neurogenic niches of tadpoles and juvenile frogs.

Adult neurogenesis occurs in neural stem cell (NSC) niches where slow cycling stem cells give rise to faster cycling progenitors. In the adult mouse NSC niche thyroid hormone, T3, and its receptor TRα act as a neurogenic switch promoting progenitor cell cycle completion and neuronal differentiation. Little is known about whether and how T3 controls proliferation of differentially cycling cells during xenopus neurogenesis. To address this question, we first used Sox3 as a marker of stem cell and progenitor populations and then applied pulse-chase EdU/IdU incorporation experiments to identify Sox3-expressing slow cycling (NSC) and fast cycling progenitor cells. We focused on the lateral ventricle of Xenopus laevis and two distinct stages of development: late embryonic development (pre-metamorphic) and juvenile frogs (post-metamorphic). These stages were selected for their relatively stable thyroid hormone availability, either side of the major dynamic phase represented by metamorphosis. TRα expression was found in both pre and post-metamorphic neurogenic regions. However, exogenous T3 treatment only increased proliferation of the fast cycling Sox3+ cell population in post-metamorphic juveniles, having no detectable effect on proliferation in pre-metamorphic tadpoles. We hypothesised that the resistance of proliferative cells to exogenous T3 in pre-metamorphic tadpoles could be related to T3 inactivation by the inactivating Deiodinase 3 enzyme. Expression of dio3 was widespread in the tadpole neurogenic niche, but not in the juvenile neurogenic niche. Use of a T3-reporter transgenic line showed that in juveniles, T3 had a direct transcriptional effect on rapid cycling progenitors. Thus, the fast cycling progenitor cells in the neurogenic niche of tadpoles and juvenile frogs respond differentially to T3 as a function of developmental stage.

Thyroid hormone effects on Krox-24 transcription in the post-natal mouse brain are developmentally regulated but are not correlated with mitosis.

Krox-24 (NGFI-A, Egr-1) is an immediate-early gene encoding a zinc finger transcription factor. As Krox-24 is expressed in brain areas showing post-natal neurogenesis during a thyroid hormone (T3)-sensitive period, we followed T3 effects on Krox-24 expression in newborn mice. We analysed whether regulation was associated with changes in mitotic activity in the subventricular zone and the cerebellum. In vivo T3-dependent Krox-24 transcription was studied by polyethylenimine-based gene transfer. T3 increased transcription from the Krox-24 promoter in both areas studied at post-natal day 2, but was without effect at day 6. An intact thyroid hormone response element (TRE) in the Krox-24 promoter was necessary for these inductions. These stage-dependent effects were also seen in endogenous Krox-24 mRNA levels: activation at day 2 and no effect at day 6. Moreover, similar results were obtained by examining beta-galactosidase expression in heterozygous mice in which one allele of the Krox-24 gene was disrupted with an inframe Lac-Z insertion. However, bromodeoxyuridine incorporation showed mitosis to continue through to day 6. We conclude first, that T3 activates Krox-24 transcription during early post-natal mitosis but that this effect is extinguished as development proceeds and second, loss of T3-dependent Krox-24 expression is not correlated with loss of mitotic activity.

Homeostatic regulation of serotonergic function by the serotonin transporter as revealed by nonviral gene transfer.

With the aim of exploring the relationship between the serotonin transporter (5-HTT or SERT) and the activity level of serotonin (5-HT) neurotransmission, in vivo expression of this protein was specifically altered using a nonviral DNA transfer method. Plasmids containing the entire coding sequence or a partial antisense sequence of the 5-HTT gene were complexed with the cationic polymer polyethylenimine and injected into the dorsal raphe nucleus of adult male rats. Significant increase or decrease in both [(3)H]citalopram binding and [(3)H]5-HT synaptosomal uptake were observed in various brain areas up to 2 weeks after a single administration of the sense plasmid or 7 d after injection of the short antisense plasmid, respectively. Such changes in 5-HTT expression were associated with functional alterations in 5-HT neurotransmission, as shown by the increased capacity of 5-HT(1A) receptor stimulation to enhance [(35)S]GTP-gamma-S binding onto the dorsal raphe nucleus in sections from rats injected with the sense plasmid. Conversely, both a decrease in 5-HT(1A)-mediated [(35)S]GTP-gamma-S binding and a reduced potency of the 5-HT(1A) receptor agonist ipsapirone to inhibit neuronal firing were observed in the dorsal raphe nucleus of antisense plasmid-injected rats. Furthermore, changes in brain 5-HT and/or 5-HIAA levels, and sleep wakefulness circadian rhythm in the latter animals demonstrated that altered expression of 5-HTT by recombinant plasmids has important functional consequences on central 5-HT neurotransmission in adult rats.

Assignment of the beta-thyroid hormone receptor to 3,5,3'-triiodothyronine-dependent inhibition of transcription from the thyrotropin-releasing hormone promoter in chick hypothalamic neurons.

Thyroid hormone, T3, is essential to the normal development and metabolism of vertebrates. Fine tuning of circulating levels of T3 is critical and involves feedback inhibition of the TRH and TSH genes by T3 at the hypothalamic and hypophyseal levels. However, the molecular basis of T3 inhibition of TRH gene expression in the hypothalamus is not known. The actions of T3 on target gene expression are mediated through nuclear receptor proteins, TR alpha and TR beta. To examine their effects on T3-dependent transcription from the rat TRH promoter, we used a gene transfer technique to express TR alpha and TR beta in cultured embryonic chick hypothalamic cells. Transcription from the TRH promoter construct transfected into these cultures was depressed in the presence of 10(-9) M T3. Cotransfecting TR alpha or TR beta activated transcription from the TRH promoter. However, only TR beta-dependent TRH transcription was differentially modulated by T3. Physiological concentrations of T3 decreased TR beta-dependent TRH transcription 4-fold. Thus, when T3 levels increase, TR beta mediates inhibition of TRH expression, a key step in down-regulating the hypophyseal-thyroid axis. This study demonstrates for the first time a T3-dependent differential regulation of the TRH promoter by TR beta and not TR alpha. Thus, the negative regulation of the TRH promoter in transiently transfected primary embryonic chick hypothalamic neurons provides a useful system for studying the molecular actions of thyroid hormone receptors.

Cross-talk between signal transducer and activator of transcription (Stat5) and thyroid hormone receptor-beta 1 (TRbeta1) signaling pathways.

PRL and T3 are involved in antagonistic regulations during various developmental processes in vertebrate species. We have studied cross-talk between transcription factors activated by these signaling pathways, i.e. signal transducer and activator of transcription 5 (Stat5) and thyroid hormone receptor beta1 (TRbeta1). Liganded TRbeta1 in the presence of its heterodimeric partner, retinoid X receptor gamma (RXRgamma), inhibited the PRL-induced Stat5a- and Stat5b-dependent reporter gene expression by up to 60%. This T3-inhibitory effect studied on Stat5 activity was partly reversed by overexpression of a TRbeta1 dominant negative variant mutated within its nuclear localization signal (TR2A). We next showed that TRbeta1 and TR2A in the presence of RXRgamma increased and decreased, respectively, Stat5 localization into the nucleus regardless of hormonal stimulation. Thus, our data suggest that TRbeta1 can be associated with Stat5 in the cytoplasm and may be involved in Stat5 nuclear translocation. In PRL-treated cells overexpressing TRbeta1/RXRgamma, both Stat5 and TRbeta1 were coimmunoprecipitated, indicating physical association of the two transcription factors. In these cells, addition of T3 with ovine (o)PRL decreased the amounts of total and tyrosine-phosphorylated Stat5 in the cytoplasm compared with oPRL-treated cells. In the nucleus, no clear difference was observed on Stat5 DNA-binding after treatment with PRL and T3 vs. PRL alone in TRbeta1/RXRgamma transfected cells. However, antibodies directed against TRbeta1 lowered Stat5-DNA binding and addition of the deacetylase inhibitor trichostatin A (TSA) relieved T3 inhibition on Stat5 transcriptional activity. Thus, we postulated that the negative cross-talk between TR and Stat5 on target genes could involve histone deacetylase recruitment by liganded TRbeta1.

Virofection: a new procedure to achieve stable expression of genes transferred into early embryos.

A new procedure, virofection, designed to stabilize the expression of transfected DNA has been developed. It exploits the capacity of retroviruses to integrate their genome into the chromosomes of host cells. The co-transfection of two plasmids, one carrying the genome of a defective retrovirus vector, the other one encoding all the retroviral proteins, results in a transient production of infectious virus particles. These particles can infect the neighboring cells and this leads to the stable integration of the vector genome. This procedure is time-saving and appears to be quite efficient. When applied to chicken embryonic fibroblasts cultured in vitro, it resulted in the stable expression of the lacZ gene in more than 30% of the cells, and did not induce chronic viremia. Stable lacZ expression was also achieved in chicken embryos in ovo. Virofection appears to be a promising and generally applicable method for implementing stable, safe and efficient gene transfer in vitro and in vivo.

T3-dependent physiological regulation of transcription in the Xenopus tadpole brain studied by polyethylenimine based in vivo gene transfer.

The formulation of cationic polymers of polyethylenimine (PEI) with plasmid DNA has been optimized to deliver genes into the Xenopus tadpole brain in vivo. Using intraventricular microinjections of 1 microl (containing 0.5 to 1 microg DNA) we show that the linear, low molecular weight polymer, 22 kDa PEI was significantly more efficient than a branched 25 kDa polymer. Complexes bearing a slightly positive net charge (formed with a ratio of 6 PEI amines per DNA phosphate) provided the best levels of transfection. Transgene expression was DNA-dose dependent and was maintained over 6 days, the time course of the experiment. Spatial distribution was examined using a beta-galactosidase construct and neurones expressing this transgene were found spread throughout the brain. The possibility of using this technique to evaluate physiological regulations was approached by examining the effects of tri-iodothyronine (T3), on transcription from the mammalian TRH and Krox-24 promoter sequences. Adding physiological concentrations of T3 to the aquarium water significantly reduced transcription from the rat TRH promoter whilst the same treatment increased transcription from a mouse Krox-24 -luciferase construct. Thus, PEI-DNA transfection provides a versatile and easily applied method for following physiological regulations at the transcriptional level in the tadpole brain.

Thyroid hormone regulation of germ cell-specific EF-1 alpha expression during metamorphosis of Xenopus laevis.

In situ hybridization was used to follow the distribution of the mRNAs encoding the somatic form of elongation factor 1 alpha (EF-1 alpha S) and the germinal counterparts of this factor, thesaurin a and EF-1 alpha O, throughout metamorphosis in the gonads of Xenopus laevis tadpoles. EF-1 alpha S mRNA is detected before metamorphosis in both the somatic and germ cells of the gonads. In contrast, thesaurin a and EF-1 alpha O mRNAs are first detected in spermatogonia and oogonia at stages 60-62, corresponding to the climax of metamorphosis and to the peak of circulating thyroid hormone. To determine whether thyroid hormone, the instigator of metamorphosis, is involved in regulating the expression of the germinal gene EF-1 alpha O, Xenopus XTC cells were transfected with an EF-1 alpha O promoter sequence inserted in front of the luciferase reporter gene. Addition of T3 to the cell culture medium induced a dose-dependent increase in transcription from the EF-1 alpha O promoter. This effect was enhanced when the construct was cotransfected with an expression vector for a Xenopus thyroid hormone receptor. Our data show that germ cells switch from a somatic to a germ-cell specific mode of expression during metamorphosis. Furthermore, this switch appears to be induced by thyroid hormone.

A somatic gene transfer approach using recombinant fusion proteins to map muscle-motoneuron projections in Xenopus spinal cord.

A combination of somatic gene transfer with fusion protein technology has been developed, thus providing an innovative means of mapping muscle-motoneuronal connections in Xenopus tadpole spinal cord. We analyzed whether a neuronal tracer created by the fusion of the LacZ gene to the tetanus toxin C fragment (LacZ-TTC) could be produced from plasmid DNA injected into muscle, and whether it could be released and undergo retrograde transport into motoneurons. Plasmids encoding various fusion protein constructions, with or without a signal peptide, were injected into dorsal or caudal muscles of premetamorphic tadpoles. The marker was produced in the muscle at constantly high levels. At one month post-injection, the fusion protein passed the neuromuscular junction and underwent retrograde transport into motoneurons. Transfer into motoneurons was seen for every animal injected, emphasizing the high reproducibility and efficiency of the process. No uptake of beta-gal protein into motoneurons was observed in the absence of the TTC fragment. Furthermore, no enhancement was obtained by adding a signal peptide. These results provide the first demonstration of the synthesis and transport of a TTC fusion protein produced directly from exogenous DNA in a vertebrate system.

Gene transfer into intact vertebrate embryos.

Intact chick embryos at 40 h incubation were transfected in vivo with chimeric vectors expressing chloramphenicol acetyl transferase (CAT) under different promoter sequences. The cationic lipid, dioctadecylamidoglycyl spermine (DOGS) used as the transfecting agent had no noticeable toxic effects on embryonic development. CAT activity was monitored 48 h post-transfection on homogenates of embryos dissected free of all annexes. Of the various constructs tested, those containing the AP-1 response element linked to CAT (TRE-tk-CAT) gave high expression and consistent enzyme responses within groups. Co-transfection experiments in which embryos were exposed simultaneously to a CAT vector containing the cAMP response element and to a vector expressing the catalytic subunit of protein kinase A showed that the promoters of the introduced genes can be regulated by their respective transacting factors. This method may therefore represent a general tool for introducing genes into intact vertebrate embryos at precise developmental times.

Human longevity is characterised by high thyroid stimulating hormone secretion without altered energy metabolism.

Few studies have included subjects with the propensity to reach old age in good health, with the aim to disentangle mechanisms contributing to staying healthier for longer. The hypothalamic-pituitary-thyroid (HPT) axis maintains circulating levels of thyroid stimulating hormone (TSH) and thyroid hormone (TH) in an inverse relationship. Greater longevity has been associated with higher TSH and lower TH levels, but mechanisms underlying TSH/TH differences and longevity remain unknown. The HPT axis plays a pivotal role in growth, development and energy metabolism. We report that offspring of nonagenarians with at least one nonagenarian sibling have increased TSH secretion but similar bioactivity of TSH and similar TH levels compared to controls. Healthy offspring and spousal controls had similar resting metabolic rate and core body temperature. We propose that pleiotropic effects of the HPT axis may favour longevity without altering energy metabolism.

Direct gene transfer into skeletal muscle in vivo: factors affecting efficiency of transfer and stability of expression.

Striated muscle is the only tissue found to be capable of taking up and expressing reporter genes that are transferred in the form of plasmid DNA. Thus, direct gene transfer is a potential method of gene therapy for the primary inherited myopathies. However, results to date have had insufficient and too variable expression to consider using direct gene transfer in human trials. We have determined that much of the variability of expression is due to nonuniform distribution of substances injected into skeletal muscle in vivo, and have developed a model to ameliorate this. Preinjection of muscles with a relatively large volume of hypertonic sucrose improves the distribution of injected substances and results in significantly less variable expression of reporter genes for luciferase or beta-galactosidase; the coefficient of variation for mean luciferase activity was reduced from about 120% to 25%. Expression is not directly proportional to dose, but is more so if the muscles are preinjected with sucrose than not. Expression is higher and less variable if DNA is injected in a larger than a smaller volume. The choice of promoter appears to be particularly important. Luciferase reporter gene expression from the SV40 promoter was transient and low, whereas expression driven by the Rous sarcoma virus (RSV) promoter was high and sustained, such that a 1,000-fold difference in expression could be observed. The mechanism of gene uptake is still unknown, but our findings indicate that fibers damaged by the injection procedure do not take up and express plasmid DNA.

Plasmid DNA is superior to viral vectors for direct gene transfer into adult mouse skeletal muscle.

Direct gene transfer into skeletal muscle offers several therapeutic possibilities. We assessed direct intramuscular injection of recombinant plasmids, adenovirus, or retrovirus in normal or regenerating muscles of mice. The incorporation and expression of reporter genes introduced by any of these three vectors is greater in regenerating than in mature muscle. In regenerating muscle, pure DNA and adenovirus result in equivalent numbers of fibers expressing reporter gene (> 10%), but adenovirus also induces considerable cellular infiltration. In mature muscle, recombinant DNA is better than adenovirus. Retrovirus failed to infect mature muscle fibers and was less effective than plasmid DNA or adenovirus in regenerating muscle. The surprisingly high relative efficiency of pure plasmid DNA suggests that this method will provide a simple, safe and viable alternative for gene therapy involving muscle tissue.

Lipospermine-based gene transfer into the newborn mouse brain is optimized by a low lipospermine/DNA charge ratio.

Nonviral, plasmid-based gene transfer into somatic tissues offers the prospect of various simple and safe therapeutic possibilities as well as applications in fundamental research. Although cationic lipids display efficient transfection activities in many in vitro systems, only low success rates using these vectors in vivo have been reported. We succeeded in defining conditions providing high levels of in vivo transfection in the brains of newborn mice. Our hypothesis was that conditions favorable for in vitro transfection (highly positively charged particles) were unlikely to be appropriate for in vivo conditions. When using the cationic lipid dioctadecylamido glycylspermine (Transfectam, DOGS) with a cytomegalovirus (CMV)-luciferase reporter gene, the best levels of transfection were obtained when using a low ratio of positive charges (supplied by the DOGS) to negative charges (carried by the DNA). Moreover, addition of the neutral lipid dioleoylphosphatidyl ethanolamine (DOPE) significantly enhanced transfection. Expression of the transgene diminished over time, independently of lipopolysaccharide content of the plasmid preparation used. This suggests that either a mitotic population of cells was preferentially transfected, or that promoter silencing was occurring. Histological examination of the spatial distribution of a beta-galactosidase-expressing transgene showed numerous groups of transfected cells both within the striatal parenchyma and in the paraventricular area. Thus, DNA-lipid complexes bearing overall charges close to neutrality open promising possibilities for modulating gene expression in the developing central nervous system and for therapy in the brain.

A powerful nonviral vector for in vivo gene transfer into the adult mammalian brain: polyethylenimine.

Nonviral gene transfer into the central nervous system (CNS) offers the prospect of providing safe therapies for neurological disorders and manipulating gene expression for studying neuronal function. However, results reported so far have been disappointing. We show that the cationic polymer polyethylenimine (PEI) provides unprecedentedly high levels of transgene expression in the mature mouse brain. Three different preparations of PEI (25-, 50-, and 800-kD) were compared for their transfection efficiencies in the brains of adult mice. The highest levels of transfection were obtained with the 25-kD polymer. With this preparation, DNA/PEI complexes bearing mean ionic charge ratios closest to neutrality gave the best results. Under such conditions, and using a cytomegalovirus (CMV)-luciferase construction, we obtained up to 0.4 10(6) RLU/microgram DNA (equivalent to 0.4 ng of luciferase), which is close to the values obtained using PEI to transfect neuronal cultures and the more easily transfected newborn mouse brain (10(6) RLU/microgram DNA). Widespread expression (over 6 mm3) of marker (luciferase) or functional genes (bcl2) was obtained in neurons and glia after injection into the cerebral cortex, hippocampus, and hypothalamus. Transgene expression was found more than 3 months post-injection in cortical neurons. No morbidity was observed with any of the preparations used. Thus, PEI, a low-toxicity vector, appears to have potential for fundamental research and genetic therapy of the brain.