Regine Heilbronn

Topors acts as a SUMO-1 E3 ligase for p53 in vitro and in vivo.

Human Topors, which was originally identified as cellular binding partner of DNA topoisomerase I and of p53, has recently been shown to function as an ubiquitin E3 ligase for p53 in a manner dependent on its N′‐terminally located RING finger. Here, we demonstrate that Topors also enhances the conjugation of the small ubiquitin‐like modifier 1 (SUMO‐1) to p53 in vivo and in a reconstituted in vitro system. The Topors SUMO‐1 E3 ligase activity does not depend upon its RING finger motif. In HeLa cells, Topors induced p53 sumoylation was accompanied by an increase in endogenous p53 protein levels. Furthermore, Topors enhances the sumoylation of a variety of other, yet unidentified, cellular proteins.

The Central and Basolateral Amygdala Are Critical Sites of Neuropeptide Y/Y2 Receptor-Mediated Regulation of Anxiety and Depression

Anxiety is integrated in the amygdaloid nuclei and involves the interplay of the amygdala and various other areas of the brain. Neuropeptides play a critical role in regulating this process. Neuropeptide Y (NPY), a 36 aa peptide, is highly expressed in the amygdala. It exerts potent anxiolytic effects through cognate postsynaptic Y1 receptors, but augments anxiety through presynaptic Y2 receptors. To identify the precise anatomical site(s) of Y2-mediated anxiogenic action, we investigated the effect of site-specific deletion of the Y2 gene in amygdaloid nuclei on anxiety and depression-related behaviors in mice. Ablating the Y2 gene in the basolateral and central amygdala resulted in an anxiolytic phenotype, whereas deletion in the medial amygdala or in the bed nucleus of the stria terminalis had no obvious effect on emotion-related behavior. Deleting the Y2 receptor gene in the central amygdala, but not in any other amygdaloid nucleus, resulted in an added antidepressant-like effect. It was associated with a reduction of presumably presynaptic Y2 receptors in the stria terminalis/bed nucleus of the stria terminalis, the nucleus accumbens, and the locus ceruleus. Our results are evidence of the highly site-specific nature of the Y2-mediated function of NPY in the modulation of anxiety- and depression-related behavior. The activity of NPY is likely mediated by the presynaptic inhibition of GABA and/or NPY release from interneurons and/or efferent projection neurons of the basolateral and central amygdala.

Viral Vectors for Gene Transfer: Current Status of Gene Therapeutics

Gene therapy for the correction of inherited or acquired disease has gained increasing importance in recent years. Successful treatment of children suffering from severe combined immunodeficiency (SCID) was achieved using retrovirus vectors for gene transfer. Encouraging improvements of vision were reported in a genetic eye disorder (LCA) leading to early childhood blindness. Adeno-associated virus (AAV) vectors were used for gene transfer in these trials. This chapter gives an overview of the design and delivery of viral vectors for the transport of a therapeutic gene into a target cell or tissue. The construction and production of retrovirus, lentivirus, and AAV vectors are covered. The focus is on production methods suitable for biopharmaceutical upscaling and for downstream processing. Quality control measures and biological safety considerations for the use of vectors in clinical trials are discussed.

Integration Preferences of Wildtype AAV-2 for Consensus Rep-Binding Sites at Numerous Loci in the Human Genome

Adeno-associated virus type 2 (AAV) is known to establish latency by preferential integration in human chromosome 19q13.42. The AAV non-structural protein Rep appears to target a site called AAVS1 by simultaneously binding to Rep-binding sites (RBS) present on the AAV genome and within AAVS1. In the absence of Rep, as is the case with AAV vectors, chromosomal integration is rare and random. For a genome-wide survey of wildtype AAV integration a linker-selection-mediated (LSM)-PCR strategy was designed to retrieve AAV-chromosomal junctions. DNA sequence determination revealed wildtype AAV integration sites scattered over the entire human genome. The bioinformatic analysis of these integration sites compared to those of rep-deficient AAV vectors revealed a highly significant overrepresentation of integration events near to consensus RBS. Integration hotspots included AAVS1 with 10% of total events. Novel hotspots near consensus RBS were identified on chromosome 5p13.3 denoted AAVS2 and on chromsome 3p24.3 denoted AAVS3. AAVS2 displayed seven independent junctions clustered within only 14 bp of a consensus RBS which proved to bind Rep in vitro similar to the RBS in AAVS3. Expression of Rep in the presence of rep-deficient AAV vectors shifted targeting preferences from random integration back to the neighbourhood of consensus RBS at hotspots and numerous additional sites in the human genome. In summary, targeted AAV integration is not as specific for AAVS1 as previously assumed. Rather, Rep targets AAV to integrate into open chromatin regions in the reach of various, consensus RBS homologues in the human genome.

OneBac: Platform for Scalable and High-Titer Production of Adeno-Associated Virus Serotype 1–12 Vectors for Gene Therapy

Scalable and genetically stable recombinant adeno-associated virus (rAAV) production systems combined with facile adaptability for an extended repertoire of AAV serotypes are required to keep pace with the rapidly increasing clinical demand. For scalable high-titer production of the full range of rAAV serotypes 1-12, we developed OneBac, consisting of stable insect Sf9 cell lines harboring silent copies of AAV1-12 rep and cap genes induced upon infection with a single baculovirus that also carries the rAAV genome. rAAV burst sizes reach up to 5 × 10(5) benzonase-resistant, highly infectious genomic particles per cell, exceeding typical yields of current rAAV production systems. In contrast to recombinant rep/cap baculovirus strains currently employed for large-scale rAAV production, the Sf9rep/cap cell lines are genetically stable, leading to undiminished rAAV burst sizes over serial passages. Thus, OneBac combines full AAV serotype options with the capacity for stable scale-up production, the current bottleneck for the transition of AAV from gene therapy trials to routine clinical treatment.

Adeno-associated virus type 2-mediated inhibition of human immunodeficiency virus type 1 (HIV-1) replication: involvement of p78rep/p68rep and the HIV-1 long terminal repeat.

Microinjection of wild-type adeno-associated virus type 2 (AAV-2) DNA and infectious human immunodeficiency virus type 1 (HIV-1) proviral DNA into the nuclei of human epithelioid SW480 cells leads to specific inhibition of HIV-1 replication. Mutational analysis of the AAV genome showed that this negative interference can be assigned to a functional AAV-2 rep gene. Moreover, the p78rep/p68rep proteins are sufficient for the anti-HIV-1 effects. The rep gene also inhibits the expression of a chloramphenicol acetyl-transferase (CAT) gene driven by the U3/R portion of the HIV-1 long terminal repeat (LTR) in the absence of tat expression. This suggests that the U3/R portion of HIV-1 contains elements responsible for the AAV-2 rep-mediated inhibition of HIV-1 LTR-driven CAT gene expression and, probably, also of HIV-1 replication. The results add support for the general significance of AAV-2 and specifically the rep gene as tools for down-regulating heterologous gene expression.

Topors, a p53 and topoisomerase I binding protein, interacts with the adeno-associated virus (AAV-2) Rep78/68 proteins and enhances AAV-2 gene expression.

The adeno-associated virus type 2 (AAV-2) Rep proteins are essential for AAV DNA replication and regulation of AAV gene expression. We have identified a cellular protein interacting with Rep78 and Rep68 in yeast two-hybrid analysis and in GST pull-down assays. This protein has recently been described as both a p53 (p53BP3) and a topoisomerase I interacting protein (Topors). It contains an arginine/serine-rich domain, a RING finger domain and five PEST sequences. A minimal sequence sufficient for interaction with Rep was mapped to Topors amino acids 871 to 917. We show that the same region is also involved in the interaction with p53. Rep sequences involved in interaction with Topors were mapped to Rep amino acids 172 to 481. Overexpression of Topors stimulated AAV gene expression in the absence of helper virus, suggesting a function of Topors as a transcriptional regulator.

The E3 ligase Topors induces the accumulation of polysumoylated forms of DNA topoisomerase I in vitro and in vivo.

Human Topors has originally been identified as binding partner of p53 and DNA topoisomerase I (TOP1). It can function as both an ubiquitin and SUMO‐1 E3 ligase for p53. Here we demonstrate that Topors enhances the formation of high‐molecular weight SUMO‐1 conjugates of TOP1 in a reconstituted in vitro system and also in human osteosarcoma cells, similar to treatment with CPT. In contrast to the situation observed with p53, overall sumoylation levels were rather unaffected. Experiments with TOP1 point mutants strongly suggest that the high‐molecular weight conjugates represent SUMO‐1 chains formed on a limited number of SUMO‐1 acceptor sites.

Differential Adeno-Associated Virus Serotype-Specific Interaction Patterns with Synthetic Heparins and Other Glycans

ABSTRACT All currently identified primary receptors of adeno-associated virus (AAV) are glycans. Depending on the AAV serotype, these carbohydrates range from heparan sulfate proteoglycans (HSPG), through glycans with terminal α2-3 or α2-6 sialic acids, to terminal galactose moieties. Receptor identification has largely relied on binding to natural compounds, defined glycan-presenting cell lines, or enzyme-mediated glycan modifications. Here, we describe a comparative binding analysis of highly purified, fluorescent-dye-labeled AAV vectors of various serotypes on arrays displaying over 600 different glycans and on a specialized array with natural and synthetic heparins. Few glycans bind AAV specifically in a serotype-dependent manner. Differential glycan binding was detected for the described sialic acid-binding AAV serotypes 1, 6, 5, and 4. The natural heparin binding serotypes AAV2, -3, -6, and -13 displayed differential binding to selected synthetic heparins. AAV7, -8, -rh.10, and -12 did not bind to any of the glycans present on the arrays. For discrimination of AAV serotypes 1 to 6 and 13, minimal binding moieties are identified. This is the first study to differentiate the natural mixed heparin binding AAV serotypes 2, 3, 6, and 13 by differential binding to specific synthetic heparins. Also, sialic acid binding AAVs display differential glycan binding specificities. The findings are relevant for further dissection of AAV host cell interaction. Moreover, the definition of single AAV-discriminating glycan binders opens the possibility for glycan microarray-based discrimination of AAV serotypes in gene therapy.

Kinetics and Frequency of Adeno-Associated Virus Site-Specific Integration into Human Chromosome 19 Monitored by Quantitative Real-Time PCR

ABSTRACT Adeno-associated virus type 2 (AAV-2) integrates specifically into a site on human chromosome 19 (chr-19) called AAVS1. To study the kinetics and frequency of chr-19-specific integration after AAV infection, we developed a rapid, sensitive, and quantitative real-time PCR assay for AAV inverted terminal repeat-chr-19-specific junctions. Despite the known variability of junction sites, conditions were established that ensured reliable quantification of integration rates within hours after AAV infection. The overall integration frequency was calculated to peak at between 10 and 20% of AAV-infected, unselected HeLa cells. At least 1 in 1,000 infectious AAV-2 particles was found to integrate site specifically up to day 4 postinfection in the absence of selection. Chromosomal breakpoints within AAVS1 agreed with those found in latently infected clonal cell lines and transgenic animals. Use of this quantitative real-time PCR will greatly facilitate the study of the early steps of wild-type and recombinant AAV vector integration.