Uracil-containing DNA in Drosophila: stability, stage-specific accumulation, and developmental involvement.

Base-excision repair and control of nucleotide pools safe-guard against permanent uracil accumulation in DNA relying on two key enzymes: uracil-DNA glycosylase and dUTPase. Lack of the major uracil-DNA glycosylase UNG gene from the fruit fly genome and dUTPase from fruit fly larvae prompted the hypotheses that i) uracil may accumulate in Drosophila genomic DNA where it may be well tolerated, and ii) this accumulation may affect development. Here we show that i) Drosophila melanogaster tolerates high levels of uracil in DNA; ii) such DNA is correctly interpreted in cell culture and embryo; and iii) under physiological spatio-temporal control, DNA from fruit fly larvae, pupae, and imago contain greatly elevated levels of uracil (200-2,000 uracil/million bases, quantified using a novel real-time PCR-based assay). Uracil is accumulated in genomic DNA of larval tissues during larval development, whereas DNA from imaginal tissues contains much less uracil. Upon pupation and metamorphosis, uracil content in DNA is significantly decreased. We propose that the observed developmental pattern of uracil-DNA is due to the lack of the key repair enzyme UNG from the Drosophila genome together with down-regulation of dUTPase in larval tissues. In agreement, we show that dUTPase silencing increases the uracil content in DNA of imaginal tissues and induces strong lethality at the early pupal stages, indicating that tolerance of highly uracil-substituted DNA is also stage-specific. Silencing of dUTPase perturbs the physiological pattern of uracil-DNA accumulation in Drosophila and leads to a strongly lethal phenotype in early pupal stages. These findings suggest a novel role of uracil-containing DNA in Drosophila development and metamorphosis and present a novel example for developmental effects of dUTPase silencing in multicellular eukaryotes. Importantly, we also show lack of the UNG gene in all available genomes of other Holometabola insects, indicating a potentially general tolerance and developmental role of uracil-DNA in this evolutionary clade.

Highly Sensitive and Rapid Characterization of the Development of Synchronized Blood Stage Malaria Parasites Via Magneto-Optical Hemozoin Quantification.

The rotating-crystal magneto-optical diagnostic (RMOD) technique was developed as a sensitive and rapid platform for malaria diagnosis. Herein, we report a detailed in vivo assessment of the synchronized Plasmodium vinckei lentum strain blood-stage infections by the RMOD method and comparing the results to the unsynchronized Plasmodium yoelii 17X-NL (non-lethal) infections. Furthermore, we assess the hemozoin production and clearance dynamics in chloroquine-treated compared to untreated self-resolving infections by RMOD. The findings of the study suggest that the RMOD signal is directly proportional to the hemozoin content and closely follows the actual parasitemia level. The lack of long-term accumulation of hemozoin in peripheral blood implies a dynamic equilibrium between the hemozoin production rate of the parasites and the immune system's clearing mechanism. Using parasites with synchronous blood stage cycle, which resemble human malaria parasite infections with Plasmodium falciparum and Plasmodium vivax, we are demonstrating that the RMOD detects both hemozoin production and clearance rates with high sensitivity and temporal resolution. Thus, RMOD technique offers a quantitative tool to follow the maturation of the malaria parasites even on sub-cycle timescales.

Secondary Structure Prediction of Protein Constructs Using Random Incremental Truncation and Vacuum-Ultraviolet CD Spectroscopy.

A novel uracil-DNA degrading protein factor (termed UDE) was identified in Drosophila melanogaster with no significant structural and functional homology to other uracil-DNA binding or processing factors. Determination of the 3D structure of UDE is excepted to provide key information on the description of the molecular mechanism of action of UDE catalysis, as well as in general uracil-recognition and nuclease action. Towards this long-term aim, the random library ESPRIT technology was applied to the novel protein UDE to overcome problems in identifying soluble expressing constructs given the absence of precise information on domain content and arrangement. Nine constructs of UDE were chosen to decipher structural and functional relationships. Vacuum ultraviolet circular dichroism (VUVCD) spectroscopy was performed to define the secondary structure content and location within UDE and its truncated variants. The quantitative analysis demonstrated exclusive α-helical content for the full-length protein, which is preserved in the truncated constructs. Arrangement of α-helical bundles within the truncated protein segments suggested new domain boundaries which differ from the conserved motifs determined by sequence-based alignment of UDE homologues. Here we demonstrate that the combination of ESPRIT and VUVCD spectroscopy provides a new structural description of UDE and confirms that the truncated constructs are useful for further detailed functional studies.

Combination of Pharmacophore Matching, 2D Similarity Search, and In Vitro Biological Assays in the Selection of Potential 5-HT6 Antagonists from Large Commercial Repositories.

Rapid in silico selection of target-focused libraries from commercial repositories is an attractive and cost-effective approach. If structures of active compounds are available, rapid 2D similarity search can be performed on multimillion compound databases, but the generated library requires further focusing. We report here a combination of the 2D approach with pharmacophore matching which was used for selecting 5-HT6 antagonists. In the first screening round, 12 compounds showed >85% antagonist efficacy of the 91 screened. For the second-round (hit validation) screening phase, pharmacophore models were built, applied, and compared with the routine 2D similarity search. Three pharmacophore models were created based on the structure of the reference compounds and the first-round hit compounds. The pharmacophore search resulted in a high hit rate (40%) and led to novel chemotypes, while 2D similarity search had slightly better hit rate (51%), but lacking the novelty. To demonstrate the power of the virtual screening cascade, ligand efficiency indices were also calculated and their steady improvement was confirmed.

Association of RNA with the uracil-DNA-degrading factor has major conformational effects and is potentially involved in protein folding.

Recently, a novel uracil-DNA-degrading factor protein (UDE) was identified in Drosophila melanogaster, with homologues only in pupating insects. Its unique uracil-DNA-degrading activity and a potential domain organization pattern have been described. UDE seems to be the first representative of a new protein family with unique enzyme activity that has a putative role in insect development. In addition, UDE may also serve as potential tool in molecular biological applications. Owing to lack of homology with other proteins with known structure and/or function, de novo data are required for a detailed characterization of UDE structure and function. Here, experimental evidence is provided that recombinant protein is present in two distinct conformers. One of these contains a significant amount of RNA strongly bound to the protein, influencing its conformation. Detailed biophysical characterization of the two distinct conformational states (termed UDE and RNA-UDE) revealed essential differences. UDE cannot be converted into RNA-UDE by addition of the same RNA, implying putatively joint processes of RNA binding and protein folding in this conformational species. By real-time PCR and sequencing after random cloning, the bound RNA pool was shown to consist of UDE mRNA and the two ribosomal RNAs, also suggesting cotranslational RNA-assisted folding. This finding, on the one hand, might open a way to obtain a conformationally homogeneous UDE preparation, promoting successful crystallization; on the other hand, it might imply a further molecular function of the protein. In fact, RNA-dependent complexation of UDE was also demonstrated in a fruit fly pupal extract, suggesting physiological relevance of RNA binding of this DNA-processing enzyme.

Physiological truncation and domain organization of a novel uracil-DNA-degrading factor.

Uracil in DNA is usually considered to be an error, but it may be used for signaling in Drosophila development via recognition by a novel uracil-DNA-degrading factor (UDE) [(Bekesi A et al. (2007) Biochem Biophys Res Commun 355, 643-648]. The UDE protein has no detectable similarity to any other uracil-DNA-binding factors, and has no structurally or functionally described homologs. Here, a combination of theoretical and experimental analyses reveals the domain organization and DNA-binding pattern of UDE. Sequence alignments and limited proteolysis with different proteases show extensive protection by DNA at the N-terminal duplicated conserved motif 1A/1B segment, and a well-folded domain within the C-terminal half encompassing conserved motifs 2-4. Theoretical structure prediction suggests that motifs 1A and 1B fold as similar alpha-helical bundles, and reveals two conserved positively charged surface patches that may bind DNA. CD spectroscopy also supports the presence of alpha-helices in UDE. Full functionality of a physiologically occurring truncated isoform in Tribolium castaneum lacking one copy of the N-terminal conserved motif 1 is revealed by activity assays of a representative truncated construct of Drosophila melanogaster UDE. Gel filtration and analytical ultracentrifugation results, together with analysis of predicted structural models, suggest a possible dimerization mechanism for preserving functionality of the truncated isoform.

A novel fruitfly protein under developmental control degrades uracil-DNA.

Uracil in DNA may arise by cytosine deamination or thymine replacement and is removed during DNA repair. Fruitfly larvae lack two repair enzymes, the major uracil-DNA glycosylase and dUTPase, and may accumulate uracil-DNA. We asked if larval tissues contain proteins that specifically recognize uracil-DNA. We show that the best hit of pull-down on uracil-DNA is the protein product of the Drosophila melanogaster gene CG18410. This protein binds to both uracil-DNA and normal DNA but degrades only uracil-DNA; it is termed Uracil-DNA Degrading Factor (UDE). The protein has detectable homology only to a group of sequences present in genomes of pupating insects. It is under detection level in the embryo, most of the larval stages and in the imago, but is strongly upregulated right before pupation. In Schneider 2 cells, UDE mRNA is upregulated by ecdysone. UDE represents a new class of proteins that process uracil-DNA with potential involvement in metamorphosis.