High levels of DNA methyltransferase 1 (DNMT1), hypermethylation, and downregulation of GAD(67) and reelin have been described in GABAergic interneurons of patients with schizophrenia (SZ) and bipolar (BP) disorders. However, overexpression of DNMT1 is lethal, making it difficult to assess the direct effect of high levels of DNMT1 on neuronal development in vivo. We therefore used Dnmt1(tet/tet) mouse ES cells that overexpress DNMT1 as an in vitro model to investigate the impact of high levels of DNMT1 on neuronal differentiation. Although there is down-regulation of DNMT1 during early stages of differentiation in wild type and Dnmt1(tet/tet) ES cell lines, neurons derived from Dnmt1(tet/tet) cells showed abnormal dendritic arborization and branching. The Dnmt1(tet/tet) neuronal cells also showed elevated levels of functional N-methyl d-aspartate receptor (NMDAR), a feature also reported in some neurological and neurodegenerative disorders. Considering the roles of reelin and GAD(67) in neuronal networking and excitatory/inhibitory balance, respectively, we studied methylation of these genes' promoters in Dnmt1(tet/tet) ES cells and neurons. Both reelin and GAD(67) promoters were not hypermethylated in the Dnmt1(tet/tet) ES cells and neurons, suggesting that overexpression of DNMT1 may not directly result in methylation-mediated repression of these two genes. Taken together, our results suggest that overexpression of DNMT1 in ES cells results in an epigenetic change prior to the onset of differentiation. This epigenetic change in turn results in abnormal neuronal differentiation and upregulation of functional NMDA receptor.

Insulators or chromatin boundary are DNA elements that organize the genome into discrete regulatory domains by limiting the actions of enhancers and silencers through a "positional-blocking mechanism". The role of these sequences, both in modulation of the enhancers range of action (enhancer-promoter selectivity) and in the organization of the chromatin in functional domains, is emerging strongly in these last years. There is a great interest in identifying new insulators because deeper knowledge of these elements can help understand how cis-regulatory elements coordinate the expression of the target genes. However, while insulators are critical in gene regulation and genome functioning, only a few have been reported so far. Here, we describe a new insulator sequence that is located in the 5'UTR of the Drosophila retrotransposon ZAM. We have used an "enhancer-blocking assay" to test its effects on the activity of the enhancer in transiently transfected Drosophila S2R(+) cell line. Moreover, we show that the new insulator is able to affect significantly the enhancer-promoter interaction in the human cell line HEK293. These results suggest the possibility of employing the ZAM insulator in gene transfer protocols from insects to mammals in order to counteract the transgene positional and genotoxic effects.

Deletion analysis of mouse DNMT1, the primary maintenance methyltransferase in mammals, showed that most of the N-terminal regulatory domain (amino acid residues 412-1112) is required for its enzymatic activity. Although analysis of deletion mutants helps to identify regions of a protein sequence required for a particular activity, amino acid deletions can have drastic effects on protein structure and/or stability. Alternative approaches represented by rational design and directed evolution are resource demanding, and require high-throughput selection or screening systems. We developed Regional Frame-shift Mutagenesis (RFM) as a new approach to identify portions required for the methyltransferase activity of DNMT1 within the N-terminal 89-905 amino acids. In this method, a short stretch of amino acids in the wild-type protein is converted to a different amino acid sequence. The resultant mutant protein retains the same amino acid length as the wild type, thereby reducing physical constrains on normal folding of the mutant protein. Using RFM, we identified three small regions in the amino-terminal one-third of the protein that are essential for DNMT1 function. Two of these regions (amino acids 124-160 and 341-368) border a large disordered region that regulates maintenance methylation activity. This organization of DNMT1's amino terminus suggests that the borders define the position of the disordered region within the DNMT1 protein, which in turn allows for its proper function.

Reprogramming of DNA methylation patterns during mammalian preimplantation development involves the concurrent maintenance of methylation on differentially methylated domains (DMDs) of imprinted genes and a marked reduction of global (non-DMD) genomic methylation. In the developing mammalian embryo, one allele of a DMD is unmethylated, and the opposite parental allele is methylated, having inherited this methylation from the parental gamete. The maintenance of DMDs is important for monoallelic imprinted gene expression and normal development of the embryo. Because the DNMT1 cytosine methyltransferase governs maintenance methylation in mammals, rearrangements of non-DMD, but not DMD methylation in preimplantation embryos suggest that the preimplantation DNMT1-dependent maintenance mechanism specifically targets DMD sequences. We explored this possibility using an engineered mouse ES cell line to screen for mutant DNMT1 proteins that protect against the loss of DMD and/or global (non-DMD) methylation in the absence of the wild-type endogenous DNMT1 methyltransferase. We identified DNMT1 mutants that were defective in maintenance of either DMD and/or non-DMD methylation. Among these, one mutant maintained non-DMD methylation but not imprinted DMD methylation and another mutant maintained just DMD methylation. The mutated amino acids of these mutants reside in a mammal-specific, disordered region near the amino terminus of DNMT1. These findings suggest that DNMT1 participates in epigenetic reprogramming through its ability to distinguish different categories of methylated sequences.

ABSTRACT: BACKGROUND: Establishing a suitable level of exogenous gene expression in mammalian cells in general, and embryonic stem (ES) cells in particular, is an important aspect of understanding pathways of cell differentiation, signal transduction and cell physiology. Despite its importance, this process remains challenging because of the poor correlation between the presence of introduced exogenous DNA and its transcription. Consequently, many transfected cells must be screened to identify those with an appropriate level of expression. To improve the screening process, we investigated the utility of the human interleukin 12 (IL-12) p40 cDNA as a reporter gene for studies of mammalian gene expression and for high-throughput screening of engineered mouse embryonic stem cells. RESULTS: A series of expression plasmids were used to study the utility of IL-12 p40 as an accurate reporter of gene activity. These studies included a characterization of the IL-12 p40 expression system in terms of :(i) a time course of IL-12 p40 accumulation in the medium of transfected cells;(ii) the dose-response relationship between the input DNA and IL-12 p40 mRNA levels and IL-12 p40 protein secretion;(iii) the utility of IL-12 p40 as a reporter gene for analyzing the activity of cis-acting genetic elements;(iv) expression of the IL-12 p40 reporter protein driven by an IRES element in a bicistronic mRNA;(v) utility of IL-12 p40 as a reporter gene in a high-throughput screening strategy to identify successful transformed mouse embryonic stem cells;(vi) demonstration of pluripotency of IL-12 p40 expressing ES cells in vitro and in vivo; and (vii) germline transmission of the IL-12 p40 reporter gene. CONCLUSION: IL-12 p40 showed several advantages as a reporter gene in terms of sensitivity and ease of the detection procedure. The IL-12 p40 assay was rapid and simple, in as much as the reporter protein secreted from the transfected cells was accurately measured by ELISA using a small aliquot of the culture medium. Remarkably, expression of Il-12 p40 does not affect the pluripotency of mouse ES cells. To our knowledge, human IL-12 p40 is the first secreted reporter protein suitable for high-throughput screening of mouse ES cells. In comparison to other secreted reporters, such as the widely used alkaline phosphatase (SEAP) reporter, the IL-12 p40 reporter system offers other real advantages.

Genomic imprinting is a conserved epigenetic phenomenon in eutherian mammals, with regards both to the genes that are imprinted and the mechanism underlying the expression of just one of the parental alleles. Epigenetic modifications of alleles of imprinted genes are established during oogenesis and spermatogenesis, and these modifications are then inherited. Differentially methylated domains (DMDs) of imprinted genes are the genomic sites of these inherited epigenetic imprints. We previously showed that CpG-rich imperfect tandem direct repeats within three different mouse DMDs (Snurf/Snrpn, Kcnq1 and Igf2r), each with a unique sequence, play a central role in maintaining the differential methylation. This finding implicates repeat-related DNA structure, not sequence, in the imprinting mechanism. To better define the important features of this signal, we compared sequences of these three DMD tandem repeats among mammalian species. All DMD repeats contain short indirect repeats, many of which are organized into larger unit repeats. Even though the larger repeat units undergo deletion and addition during evolution (most likely through unequal crossovers during meiosis), the size of DMD tandem repeated regions has remained remarkably stable during mammalian evolution. Moreover, all three DMD tandem repeats have a high-CpG content, an ordered arrangement of CpG dinucleotides, and similar predicted secondary structures. These observations suggest that a structural feature or features of these DMD tandem repeats is the conserved DMD imprinting signal.

Studies have reported that an enhancer can act in trans when artificially, noncovalently bridged to the promoter by a protein-linked biotin:streptavidin complex, or when an enhancer and a promoter are located on separate concatenated plasmids. To investigate such transactivation in mammalian cells, we constructed CMV promoter-enhancer mutants driving the expression of the EGFP reporter gene and transfected cultured cells with various combinations of the mutant PCR products; results were analyzed using fluorescence microscopy and flow cytometry. Our results show that the CMV enhancer can stimulate transcription in trans, even in the absence of physical association of the enhancer and promoter. Furthermore, we show that the transactivation of the CMV enhancer can be strengthened by the histone deacetylase inhibitor sodium butyrate. Finally, we provide evidence that the CMV enhancer can influence, in trans, the activity of heterologous promoters. Although different mechanisms may lead to transcriptional activation when the CMV enhancer is not covalently linked to the promoter, our results suggest that the main mechanism resembles the process of transvection and may be important for gene regulation. These findings may have implications in understanding the processes that underlie gene therapy because of the potential alteration of endogenous gene expression.

BACKGROUND: The ability to deliver large (>100 kb) fragments of DNA to mammalian cells in vitro and in vivo is becoming increasingly important with the availability of BAC and PAC constructs for gene expression. Here we investigate in vitro and in vivo delivery of BACs up to 157 kb. METHODS: Different types of polyethylenimine (PEI) and Lipofectamine were used to deliver 150-kb BAC (bacterial artificial chromosome) DNA to mouse and human cell lines in tissue culture and the level of EGFP expression compared. To assess the intactness of the DNA delivered, a BAC carrying oriP/EBNA-1 was used to make stably transfected cell lines. Episomal DNA was then rescued into E. coli followed by analysis on a pulsed-field gel. Three different methods of in vivo delivery were also assessed for delivery of BAC DNA; intravenous injection of DNA/PEI particles, intramuscular injection with electroporation and high-volume injection into the tail vein. RESULTS: PEI22 (linear polymer form, 22 kDa) was found to be the most efficient method for delivery of 150-kb BAC DNA to both cell lines in tissue culture. However, Lipofectamine 2000 was found to give a higher proportion of intact DNA than PEI22 in stably transformed colonies and almost all the DNA delivered by Lipofectamine 2000 was intact. Intravenous injection of DNA/PEI particles was found to be inefficient for delivery of BAC DNA. Intramuscular injection with electroporation of pure BAC DNA was very efficient and expression was maintained for 105 days. High-volume injection of BAC DNA gave excellent expression in the liver and intact BAC DNA could be rescued 7 days after injection. CONCLUSIONS: These results demonstrate efficient delivery of intact, large (up to 157 kb) DNA constructs for in vitro gene expression and in vivo gene therapy applications.

The causative agent of severe acute respiratory syndrome (SARS) has been identified as a new type of coronavirus. Here, we have investigated the ability of adenoviral delivery of codon-optimised SARS-CoV strain Urbani structural antigens spike protein S1 fragment, membrane protein, and nucleocapsid protein to induce virus-specific broad immunity in rhesus macaques. We immunised rhesus macaques intramuscularly with a combination of the three Ad5-SARS-CoV vectors or a control vector and gave a booster vaccination on day 28. The vaccinated animals all had antibody responses against spike protein S1 fragment and T-cell responses against the nucleocapsid protein. All vaccinated animals showed strong neutralising antibody responses to SARS-CoV infection in vitro. These results show that an adenoviral-based vaccine can induce strong SARS-CoV-specific immune responses in the monkey, and hold promise for development of a protective vaccine against the SARS causal agent.