Autoantigen-specific TGFbeta-induced Foxp3+ regulatory T cells prevent autoimmunity by inhibiting dendritic cells from activating autoreactive T cells

Several strategies are being designed to test the therapeutic potential of Ag-specific regulatory T cells to prevent or treat autoimmune diseases. In this study, we demonstrate that naive CD4+ Foxp3- T cells specific for a naturally expressed autoantigen (H+/K+ ATPase) can be converted to Foxp3+ T regulatory cells (Tregs) when stimulated in presence of TGFbeta. TGFbeta-induced Tregs (iTregs) have all the characteristics of naturally generated regulatory T cells in vitro, and more importantly, are effective at preventing organ-specific autoimmunity in a murine model of autoimmune gastritis. H+/K+ ATPase specific iTregs were able to inhibit the initial priming and proliferation of autoreactive T cells, and appear to do so by acting on H+/K+ ATPase presenting dendritic cells (DC). DC exposed to iTregs in vivo were reduced in their ability to stimulate proliferation and cytokine production by H+/K+ ATPase specific T cells. iTregs specifically reduced CD80 and CD86 expression on the surface of H+/K+ ATPase presenting DC in vitro. These studies reveal the therapeutic potential of Ag specific iTregs to prevent autoimmunity, and provide a mechanism by which this population of regulatory T cells, and perhaps others, mediate their suppressive effects in vivo.     

Activation of stress-responsive promoters by ionizing radiation for deployment in targeted gene therapy

Radiotherapy is one of the principal modalities of cancer treatment, but the delivery of a curative dose of ionizing radiation (IR) to the tumour is frequently limited by the need to protect the normal tissues within the irradiated area from radiation damage. This problem could be circumvented if tumour cells could be selectively sensitized to killing by IR. One way to achieve this goal would be to transduce the tumour cells with expression vectors carrying toxin genes under the control of promoters that are inactive unless induced by IR. For this approach to be successful, two parameters must be met: (i) the expression vector has to be delivered to the tumour or its immediate vicinity (e.g. its vasculature) and (ii) the promoter driving the expression of the toxin gene has to have negligible basal activity, yet has to be activated by clinically-achievable doses of IR. Several vectors that fulfil these criteria are currently reaching clinical trials. In this review, we examine the response of mammalian cells to IR, and the current status of radiation-induced suicide gene therapy that is dependent on this response.     

Characterization and quantification of triple helix formation in chromosomal DNA

DNA-binding molecules that recognize specific sequences offer a high potential for the understanding of chromatin structure and associated biological processes in addition to their therapeutic potential, e.g. as positioning agents for validated anticancer drugs. A prerequisite for the development of DNA-binding molecules is the availability of appropriate methods to assess their binding properties quantitatively at the desired target sequence in the human genome. We have further developed a capture assay to assess triplex-forming oligonucleotide (TFO) binding efficiency quantitatively. This assay is based on bifunctional, psoralen and biotin-conjugated, TFOs and real-time PCR analysis. We have applied this novel quantification method to address two issues that are relevant for DNA-binding molecules. First, we have compared directly the extent of TFO-binding in three experimental settings with increasing similarity to the situation in vivo, i.e. naked genomic DNA, isolated cell nuclei, or whole cells. This comparison allows us to characterize factors that influence genomic triplex formation, e.g. chromosomal DNA organization or intracellular milieu. In isolated nuclei, the binding was threefold lower compared to naked DNA, consistent with a decreased target accessibility int he nucleosomal environment. Binding was detected in whole cells, indicating that the TFO enters the nucleus and binds to its target in intact cells in vivo, but the efficiency was decreased (tenfold) compared to nuclei. Secondly, we applied the method to characterize the binding properties of two different TFOs targeting the same sequence. We found that an antiparallel-binding GT-containing TFO bound more efficiently, but with less target sequence selectivity compared to a parallel-binding CU-containing TFO. Collectively, a sensitive method to characterize genomic triplex formation was described. This may be useful for the determination of factors driving TFO binding efficiency and, thus, may improve the usefulness of triplex-mediated gene targeting for studies of chromatin structure as well as for therapeutic antigene strategies.     

Direct mass spectrometry approaches to characterize polyphenol composition of complex samples

Lower molecular weight polyphenols including proanthocyanidin oligomers can be analyzed after HPLC separation on either reversed-phase or normal phase columns. However, these techniques are time consuming and can have poor resolution as polymer chain length and structural diversity increase. The detection of higher molecular weight compounds, as well as the determination of molecular weight distributions, remain major challenges in polyphenol analysis.Approaches based on direct mass spectrometry (MS) analysis that are proposed to help overcome these problems are reviewed. Thus, direct flow injection electrospray ionization mass spectrometry analysis can be used to establish polyphenol fingerprints of complex extracts such as in wine. This technique enabled discrimination of samples on the basis of their phenolic (i.e. anthocyanin, phenolic acid and flavan-3-ol) compositions, but larger oligomers and polymers were poorly detectable. Detection of higher molecular weight proanthocyanidins was also restricted with matrix-assisted laser desorption ionization (MALDI) MS, suggesting that they are difficult to desorb as gas-phase ions. The mass distribution of polymeric fractions could, however, be determined by analyzing the mass distributions of bovine serum albumin/proanthocyanidin complexes using MALDI-TOF-MS.     

Germline genomic structure of the B10.A mouseTcra-V2 gene subfamily

 The number of mouse Tcra-V gene segments varies from one individual to another and is estimated to be about 100. Southern blot analysis revealed that most of the Tcra-V are organized in clusters composed of copies of Tcra-V belonging to different subfamilies. We analyzed in detail a Tcra-V subfamily and looked for new Tcra-V in order to improve the knowledge of the mouse Tcra locus organization. A series of genomic clones derived from the B10.A mouse strain enclosing these clusters was used to determined the structure of all the Tcra-V2. We were able to identify ten Tcra-V2. This study showed that the Tcra-V2 can be organized into three structural subgroups. The distribution of the genes along the Tcra locus, plus their structural organization, indicates that successive duplications occurred during the processes of expansion and contraction of the Tcra-V gene subfamilies. Several Tcra-V2 are also identical, indicating recent duplications. The most divergent Tcra-V2 differ by 7.4% nucleotides, leading to 5.2% differences in amino acid contents. Received: 8 August 1995 / Revised: 24 April 1996     

Torque teno sus virus (TTSuV) in cell cultures and trypsin

Torque teno sus virus (TTSuV), a member of the family Anelloviridae, is a single-stranded, circular DNA virus, widely distributed in swine populations. Presently, two TTSuV genogroups are recognized: Torque teno sus virus 1 (TTSuV1) and Torque teno sus virus 2 (TTSuV2). TTSuV genomes have been found in commercial vaccines for swine, enzyme preparations and other drugs containing components of porcine origin. However, no studies have been made looking for TTSuV in cell cultures. In the present study, a search for TTSuV genomes was carried out in cell culture lineages, in sera used as supplement for cell culture media as well as in trypsin used for cell disaggregation. DNA obtained from twenty-five cell lineages (ten from cultures in routine multiplication and fifteen from frozen ampoules), nine samples of sera used in cell culture media and five batches of trypsin were examined for the presence of TTSuV DNA. Fifteen cell lineages, originated from thirteen different species contained amplifiable TTSuV genomes, including an ampoule with a cell lineage frozen in 1985. Three cell lineages of swine origin were co-infected with both TTSuV1 and TTSuV2. One batch of trypsin contained two distinct TTSuV1 plus one TTSuV2 genome, suggesting that this might have been the source of contamination, as supported by phylogenetic analyses of sequenced amplicons. Samples of fetal bovine and calf sera used in cell culture media did not contain amplifiable TTSuV DNA. This is the first report on the presence of TTSuV as contaminants in cell lineages. In addition, detection of the viral genome in an ampoule frozen in 1985 provides evidence that TTSuV contamination is not a recent event. These findings highlight the risks of TTSuV contamination in cell cultures, what may be source for contamination of biological products or compromise results of studies involving in vitro multiplied cells.     

Impact of High-Fat Diet and Early Stress on Depressive-Like Behavior and Hippocampal Plasticity in Adult Male Rats

During development, the brain goes through fundamental processes, including organization of neural networks and plasticity. Environmental interventions may change initial brain programming, leading to long-lasting effects and altering the susceptibility to psychopathologies, including depression disorder. It is known that depression is a psychiatric disorder with a high prevalence worldwide, including high rates among adolescents. In this study, we evaluated whether social isolation in the prepubertal period and chronic use of high-fat diet (HFD) may induce depressive-like behavior in male adult rats. We also investigated hippocampal plasticity markers and neurotransmitter systems. We found both social isolation and HFD induced a depressive-like behavior in the forced swimming task. Moreover, chronic HFD reduced synaptic markers in hippocampus, demonstrated by reductions in βIII-tubulin (neuronal marker), PSD-95, SNAP-25, and neurotrophin-3. The HFD group also presented decreased glutamatergic and GABAergic receptors subunits. On the other hand, stress affected hippocampal brain-derived neurotrophic factor (BDNF) signaling pathways, and increased expression of subunit of the NMDA receptor (NR2A). Both factors (stress and diet) decreased GR in the hippocampus without affecting plasma corticosterone at basal levels. Interactions between early stress and HFD access were observed only in the BNDF receptor (tropomyosin receptor kinase B; TrkB) and synaptophysin. In summary, these findings showed that a brief social isolation and chronic HFD, during a sensitive developmental period, cause depressive-like behavior in adulthood. The mechanisms underlying these behavioral effects may involve changes in the levels of synaptic proteins in hippocampus: HFD consumption appears to affect synaptic markers, while social isolation affected BDNF signaling more significantly.